Discovery
TIGR-Tas systems were reported in February 2025 by researchers at the Broad Institute of MIT and Harvard andSystem components
TIGR arrays
TIGR arrays consist of repetitive sequences organized into dual-repeat units or stem-loop structures. Each unit contains: * Edge repeats and loop repeats (8-12 nucleotides each) * Spacer A and Spacer B (typically 9 nucleotides each) * Conserved box C and box D motifs similar to those found in snoRNAsTas proteins
TIGR-associated (Tas) proteins are classified into three main types: * TasA (from '' Flavonifractor plautii''): Contains only the Nop domain * TasH (from Salicola phage): Nop domain fused with an HNH nuclease domain * TasR (from '' Thermoproteota archaeon''): Nop domain fused with a RuvC nuclease domainMechanism of action
RNA processing
TIGR arrays are transcribed and processed into 36-nucleotide guide RNAs called tigRNAs. Processing occurs at precise sites within edge repeats and requires the presence of Tas proteins, though the proteins themselves do not directly catalyze the cleavage.DNA targeting
Unlike CRISPR systems that use a single guide RNA to target one DNA strand, TIGR systems employ a tandem-spacer targeting mechanism: * Spacer A pairs with one DNA strand * Spacer B pairs with the complementary DNA strand * Both spacers must be correctly paired for efficient cleavage * No protospacer-adjacent motif (PAM) is requiredCleavage pattern
TasR nucleases create double-strand breaks with 8-nucleotide 3' overhangs, cleaving 3' to the nucleotide complementary to the 5th base of each spacer (following a "C - 5 rule").Structural features
Cryo-electron microscopy studies revealed that TasR forms a C2-symmetric dimer that binds target DNA and tigRNA. The structure shows: * Dramatic 180° DNA bending upon complex formation * Nop domains that recognize box C/D motifs in tigRNAs * RuvC domains positioned for coordinated cleavage of both DNA strandsDistribution and diversity
TIGR systems are found primarily in: * Bacteriophages and archaeal viruses * Parasitic bacteria of the Candidate Phyla Radiation * Various prokaryotic genomes Two main architectural variants exist: # Dual-repeat arrays: Traditional TIGR organization # Stem-loop arrays: Alternative organization lacking separating repeatsEvolutionary relationships
TIGR systems show evolutionary connections to: * IS110 transposases: Share structural domains and RNA-binding mechanisms * Box C/D snoRNPs: Common Nop domain architecture and box C/D motifs These relationships suggest TIGR systems may represent an ancestral form of RNA-guided systems.Applications and potential
Genome editing
TIGR-TasR systems can be successfully adapted for: * Programmable DNA cleavage in human cells * Genome editing with unique targeting propertiesAdvantages over CRISPR
TIGR-Tas systems offer several potential advantages over CRISPR technology: * No PAM requirement: Can theoretically target any genomic site * Compact size: Tas proteins are approximately one-quarter the size of Cas9, potentially facilitating cellular delivery for therapeutic applications * Dual-guide system: May enhance specificity by requiring correct recognition of both DNA strands * Modularity: Distinct functional domains that could be engineered for various applicationsTherapeutic potential
The small size and modularity of TIGR-Tas systems make them promising candidates for therapeutic gene editing applications, potentially overcoming delivery challenges associated with larger CRISPR proteins.Biological functions
While the exact biological roles remain unclear, proposed functions include: * Mobile genetic element (MGE) interference * Gene regulation * Plasmid maintenance and inheritance * Inter-MGE competitionSee also
*References
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