CRISPR-associated transposition systems allow guide RNA–directed integration of a single DNA cargo in one orientation at a fixed distance from a programmable target sequence. We used cryo–electron microscopy (cryo-EM) to define the mechanism that underlies this process by characterizing the transposition regulator, TnsC, from a type V-K CRISPR-transposase system. In this scenario, polymerization of adenosine triphosphate–bound TnsC helical filaments could explain how polarity information is passed to the transposase. TniQ caps the TnsC filament, representing a universal mechanism for target information transfer in Tn7/Tn7-like elements. Transposase-driven disassembly establishes delivery of the element only to unused protospacers. Finally, TnsC transitions to define the fixed point of insertion, as revealed by structures with the transition state mimic ADP•AlF3. These mechanistic findings provide the underpinnings for engineering CRISPR-associated transposition systems for research and therapeutic applications.
ω-Ester-containing peptides (OEPs) are a family of ribosomally synthesized and post-translationally modified peptides (RiPPs) containing intramolecular ω-ester or ω-amide bonds. Although their distinct side-to-side connections may create considerable topological diversity of multicyclic peptides, it is largely unknown how diverse ring patterns have been developed in nature. Here, using genome mining of biosynthetic enzymes of OEPs, we identified genes encoding nine new groups of putative OEPs with novel core consensus sequences, disclosing a total of ∼1500 candidate OEPs in 12 groups. Connectivity analysis revealed that OEPs from three different groups contain novel tricyclic structures, one of which has a distinct biosynthetic pathway where a single ATP-grasp enzyme produces both ω-ester and ω-amide linkages. Analysis of the enzyme cross-reactivity showed that, while enzymes are promiscuous to nonconserved regions of the core peptide, they have high specificity to the cognate core consensus sequence, suggesting that the enzyme–core pair has coevolved to create a unique ring topology within the same group and has sufficiently diversified across different groups. Collectively, our results demonstrate that the diverse ring topologies, in addition to diverse sequences, have been developed in nature with multiple ω-ester or ω-amide linkages in the OEP family of RiPPs.
CRISPR-associated transposons (CASTs) are Tn7-like elements that are capable of RNA-guided DNA integration. Although structural data are known for nearly all core transposition components, the transposase component, TnsB, remains uncharacterized. Using cryo-electron microscopy (cryo-EM) structure determination, we reveal the conformation of TnsB during transposon integration for the type V-K CAST system from Scytonema hofmanni (ShCAST). Our structure of TnsB is a tetramer, revealing strong mechanistic relationships with the overall architecture of RNaseH transposases/integrases in general, and in particular the MuA transposase from bacteriophage Mu. However, key structural differences in the C-terminal domains indicate that TnsB’s tetrameric architecture is stabilized by a different set of protein–protein interactions compared with MuA. We describe the base-specific interactions along the TnsB binding site, which explain how different CAST elements can function on cognate mobile elements independent of one another. We observe that melting of the 5′ nontransferred strand of the transposon end is a structural feature stabilized by TnsB and furthermore is crucial for donor–DNA integration. Although not observed in the TnsB strand-transfer complex, the C-terminal end of TnsB serves a crucial role in transposase recruitment to the target site. The C-terminal end of TnsB adopts a short, structured 15-residue “hook” that decorates TnsC filaments. Unlike full-length TnsB, C-terminal fragments do not appear to stimulate filament disassembly using two different assays, suggesting that additional interactions between TnsB and TnsC are required for redistributing TnsC to appropriate targets. The structural information presented here will help guide future work in modifying these important systems as programmable gene integration tools.
CRISPR-associated transposons (CAST) are programmable mobile genetic elements that insert large DNA cargos using an RNA-guided mechanism1–3. CAST elements contain multiple conserved proteins: a CRISPR effector (Cas12k or Cascade), a AAA+ regulator (TnsC), a transposase (TnsA–TnsB) and a target-site-associated factor (TniQ). These components are thought to cooperatively integrate DNA via formation of a multisubunit transposition integration complex (transpososome). Here we reconstituted the approximately 1 MDa type V-K CAST transpososome from Scytonema hofmannii (ShCAST) and determined its structure using single-particle cryo-electon microscopy. The architecture of this transpososome reveals modular association between the components. Cas12k forms a complex with ribosomal subunit S15 and TniQ, stabilizing formation of a full R-loop. TnsC has dedicated interaction interfaces with TniQ and TnsB. Of note, we observe TnsC–TnsB interactions at the C-terminal face of TnsC, which contribute to the stimulation of ATPase activity. Although the TnsC oligomeric assembly deviates slightly from the helical configuration found in isolation, the TnsC-bound target DNA conformation differs markedly in the transpososome. As a consequence, TnsC makes new protein–DNA interactions throughout the transpososome that are important for transposition activity. Finally, we identify two distinct transpososome populations that differ in their DNA contacts near TniQ. This suggests that associations with the CRISPR effector can be flexible. This ShCAST transpososome structure enhances our understanding of CAST transposition systems and suggests ways to improve CAST transposition for precision genome-editing applications.
The modular biosynthetic pathway of ribosomally synthesized and post-translationally modified peptides (RiPPs) enhances their engineering potential for exploring new structures and biological functions. The ωester-containing peptides (OEPs), a subfamily of RiPPs, have distinct side-to-side ester or amide linkages and frequently present more than one macrocyclic domain in a "beads-on-a-string" structure. In an effort to improve the engineering potential of RiPPs, we present here the idea that the multidomain architecture of an OEP, plesiocin, can be exploited to create a bifunctional modified peptide. Characterization of plesiocin variants revealed that strong chymotrypsin inhibition relies on the bicyclic structure of the domain in which a leucine residue in the hairpin loop functions as a specificity determinant. Four domains of plesiocin promote simultaneous binding of multiple enzymes, where the C-terminal domain binds chymotrypsin most efficiently. Using this information, we successfully engineered a plesiocin variant in which two different domains inhibit chymotrypsin and trypsin. This result suggests that the multidomain architecture of OEPs is a useful platform for engineering multifunctional hybrid RiPPs.Communication pubs.acs.org/biochemistry
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