Abstract
Host immune system has evolved multiple sensors to detect pathogenic and damaged DNA, where precise regulation is critical for distinguishing self from non-self. Our previous studies showed that NLRC3 is an inhibitory nucleic acid sensor that binds to viral DNA and thereby unleashing STING activation. In this study, we demonstrate that human NLRC3 favors long dsDNA, while porcine NLRC3 shows an affinity for shorter dsDNA. Mechanistically, a conserved arginine residue within the leucine-rich repeats of primates NLRC3 forms a structural bridge facilitating the binding of long dsDNA. Conversely, a glycine residue that replaces the arginine in non-primates disrupts this bridge. Furthermore, porcine NLRC3 negatively regulates type I interferon by interacting with cyclic GMP-AMP synthase (cGAS) to inhibit its DNA binding, thereby preventing cGAS activation. These results reveal an unrecognized mechanism by which a species-specific amino acid variation of NLRC3 influences nucleic acid recognition, providing insights into the evolution of innate immunity to pathogens.