Mechanism for Cas4-assisted directional spacer acquisition in CRISPR–Cas

Prokaryotes adapt to challenges from mobile genetic elements by integrating spacers derived from foreign DNA in the CRISPR array 1 . Spacer insertion is carried out by the Cas1–Cas2 integrase complex 2 – 4 . A substantial fraction of CRISPR–Cas systems use a Fe–S cluster containing Cas4 nuclease to...

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Bibliographic Details
Published in:Nature (London) 2021-10, Vol.598 (7881), p.515-520
Main Authors: Hu, Chunyi, Almendros, Cristóbal, Nam, Ki Hyun, Costa, Ana Rita, Vink, Jochem N. A., Haagsma, Anna C., Bagde, Saket R., Brouns, Stan J. J., Ke, Ailong
Format: Article
Language:English
Subjects:
101/28
45
631/326/1320
631/337/1644
631/45/535/1258/1259
631/45/607/1167
Biosynthesis
Constipation
CRISPR
CRISPR-Associated Proteins - metabolism
CRISPR-Cas Systems
Databases, Genetic
Deoxyribonucleic acid
Dissociation
DNA
Endonucleases - metabolism
Genetic research
Geobacter - enzymology
Humanities and Social Sciences
Insertion
Integrase
Integration
Interfaces
Microscopy
Models, Molecular
Molecular Conformation
Molecular interactions
multidisciplinary
Nuclease
Nucleotide Motifs
Nucleotide sequence
Prokaryotes
Restriction enzymes, DNA
Science
Science (multidisciplinary)
Spacer
Spacers
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Summary:Prokaryotes adapt to challenges from mobile genetic elements by integrating spacers derived from foreign DNA in the CRISPR array 1 . Spacer insertion is carried out by the Cas1–Cas2 integrase complex 2 – 4 . A substantial fraction of CRISPR–Cas systems use a Fe–S cluster containing Cas4 nuclease to ensure that spacers are acquired from DNA flanked by a protospacer adjacent motif (PAM) 5 , 6 and inserted into the CRISPR array unidirectionally, so that the transcribed CRISPR RNA can guide target searching in a PAM-dependent manner. Here we provide a high-resolution mechanistic explanation for the Cas4-assisted PAM selection, spacer biogenesis and directional integration by type I-G CRISPR in Geobacter sulfurreducens , in which Cas4 is naturally fused with Cas1, forming Cas4/Cas1. During biogenesis, only DNA duplexes possessing a PAM-embedded 3′-overhang trigger Cas4/Cas1–Cas2 assembly. During this process, the PAM overhang is specifically recognized and sequestered, but is not cleaved by Cas4. This ‘molecular constipation’ prevents the PAM-side prespacer from participating in integration. Lacking such sequestration, the non-PAM overhang is trimmed by host nucleases and integrated to the leader-side CRISPR repeat. Half-integration subsequently triggers PAM cleavage and Cas4 dissociation, allowing spacer-side integration. Overall, the intricate molecular interaction between Cas4 and Cas1–Cas2 selects PAM-containing prespacers for integration and couples the timing of PAM processing with the stepwise integration to establish directionality. Structures of the Cas4–Cas1–Cas2 complex from Geobacter sulfurreducens show that a 3′-overhang in the protospacer adjacent motif is required for complex assembly and spacer insertion into the CRISPR array.
ISSN:0028-0836
1476-4687
DOI:10.1038/s41586-021-03951-z