SP110 sequestration of SP100 protects against toxic filaments during innate immune signaling

Stimulation of the innate immune system by foreign RNA elicits a potent response against invading pathogens and can trigger cell death. The mechanisms by which cells balance a robust response with cell-intrinsic lethality are still being uncovered. Employing genome-wide CRISPR-Cas9 genetic screens with triphosphorylated RNA stimulation, we identify speckled protein 110 (SP110) as a potent negative regulator of type 1 interferon-driven cell death. Death suppression by SP110 counteracts a death-promoting activity of another speckled protein, SP100. Both SP110 suppression and SP100 toxicity are mediated by direct interactions between the caspase activation and recruitment domains (CARDs) in each protein. SP100-induced death is mediated by homomeric CARD filaments that are disassembled by a heteromeric CARD interaction with SP110. Overexpression of SP100 is sufficient to overwhelm normal levels of SP110, leading to genotoxicity. Using cryo-EM and AlphaFold modeling, we develop and validate an atomic description of SP100 CARD filament formation and filament breaking by SP110. Genome-wide binding studies reveal that SP110 and SP100 normally associate at active promoters, but disruption of the CARD interaction releases SP100 to form toxic filaments. Overall, we uncover a novel regulatory partnership in human innate immunity that balances signal potency with cell intrinsic lethality.