9W1E image
Deposition Date 2025-07-25
Release Date 2026-05-13
Last Version Date 2026-05-13
Entry Detail
PDB ID:
9W1E
Keywords:
Title:
The type III CRISPR-associated deaminase in complex cA6 and ATP, State 1
Biological Source:
Source Organism(s):
Expression System(s):
Method Details:
Experimental Method:
Resolution:
2.74 Å
Aggregation State:
PARTICLE
Reconstruction Method:
SINGLE PARTICLE
Macromolecular Entities
Structures with similar UniProt ID
Protein Blast
Polymer Type:polypeptide(L)
Molecule:adenosine deaminase
Gene (Uniprot):EG19_07865
Chain IDs:A, B, C, D, E, F
Chain Length:631
Number of Molecules:6
Biological Source:Thermoanaerobaculum aquaticum
Polymer Type:polyribonucleotide
Molecule:RNA (5'-R(P*AP*AP*AP*AP*AP*A)
Chain IDs:G (auth: X)
Chain Length:6
Number of Molecules:1
Biological Source:Thermoanaerobaculum aquaticum
Primary Citation
Structural and functional insights into the adenosine deaminase of the type III-B CRISPR-Cas system.
Nucleic Acids Res. 54 ? ? (2026)
PMID: 41841492 DOI: 10.1093/nar/gkag231

Abstact

Type III CRISPR-Cas (Clustered Regularly Interspaced Short Palindromic Repeats and CRISPR-associated proteins) systems confer antiviral immunity via cyclic oligoadenylate (cOA) signaling. Here, we elucidate a cooperative bacterial defense strategy involving two cOA-activated CRISPR-associated Rossmann fold (CARF)-containing effectors, adenosine deaminase CAAD and ribonuclease Csx1, in Thermoanaerobaculum aquaticum. Genomic analyses indicate widespread co-occurrence of CRISPR-associated adenosine deaminase (CAAD) with ancillary CARF-containing effectors in type III CRISPR systems, suggesting that multiple CARF-containing proteins may contribute to a coordinated cOA-dependent defense. Biochemical and structural studies reveal the intrinsic dynamics of CAAD hexamer, and demonstrate that cA4/cA6 binding stabilizes CAAD hexamers, triggering metal-ion-dependent conversion of ATP into inosine triphosphate. Concurrently, the downstream Csx1 is exclusively activated by cA4 to cleave single-stranded RNA. Strikingly, we found that both effectors are capable of degrading cA4, suggesting that this CAAD-Csx1 pair may be cross-regulated and achieve immunity through a dual-targeting mechanism: in response to infection, Csx1 degrades viral RNA while CAAD disrupts nucleotide metabolism via ATP deamination, which can be relieved via cA4 degradation when infection has been eliminated. This study proposes an enhanced defense mechanism through coordinated activation and regulation of multiple CRISPR effectors by a single signaling molecule, unveiling unprecedented complexity in CRISPR immunoregulation.

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