Mechanisms and Effects of Activation of Innate Immunity by Mitochondrial Nucleic Acids.

Abstract

In recent years, a growing number of roles have been identified for mitochondria in innate immunity. One principal mechanism is that translocation of mitochondrial nucleic acid species from the mitochondrial matrix to the cytosol and endolysosomal lumen in response to an array of microbial and non-microbial environmental stressors has been found to serve as a second messenger event in the cell signaling of the innate immune response. Thus, mitochondrial DNA and RNA have been shown to access the cytosol through several regulated mechanisms involving remodeling of the mitochondrial inner and outer membranes and to access lysosomes via vesicular transport, thereby activating cytosolic (e.g., cyclic GMP-AMP synthase [cGAS]; retinoic acid-inducible gene-I [RIG-I]-like receptors) and endolysosomal (Toll-like Receptor [TLR]7, -9) nucleic acid receptors that induce type I interferons and pro-inflammatory cytokines. In this mini-review, we discuss these molecular mechanisms of mitochondrial nucleic acid mislocalization and their roles in host defense, autoimmunity, and auto-inflammatory disorders. The emergent paradigm is one in which host-derived DNA interestingly serves as a signal amplifier in the innate immune response and also as an alarm signal for disturbances in organellar homeostasis. The apparent vast excess of mitochondria and mitochondrial DNA nucleoids per cell may thus serve to sensitize the cell response to stressors while ensuring an underlying reserve of intact mitochondria to sustain cellular metabolism. An improved understanding of these molecular mechanisms will hopefully afford future opportunities for therapeutic intervention in human disease.