Mitochondrial DNA and cGAS-STING Innate Immune Signaling Pathway: Latest Research Progress

Mitochondria are important organelles that present extensively in cells, serving diverse functions. In addition to controlling cell energy production and metabolism, mitochondria are also involved in various biological processes, including anti-infection, apoptosis, and autophagy. Harmful stimuli from external environment or those generated by the cells themselves can damage mitochondria and cause mitochondrial stress response, during which the mitochondrial matrix containing mitochondrial DNA (mtDNA) can leak into the cytoplasm. Cytoplasmic mtDNA, acting as a damage-associated molecular pattern (DAMP), can activate a panel of DNA sensors and elicit innate immune response in organisms. Cyclic GMP-AMP synthase (cGAS), a key intracellular DNA sensor, can catalyze the conversion of GTP and ATP to cyclic GMP-AMP (2′3′-cGAMP), which serves as second messenger to bind and activate stimulator of interferon gene (STING), an endoplasmic adaptor protein. Beyond its critical roles in anti-microbial immunity, cGAS-STING pathway also serves important functions in many pathological and physiological processes such as autoimmunity, tumor and senescence. In this review, we focus on how the mtDNA released during mitochonrial stress response activates the cGAS-STING innate immune signaling pathway and the associated diseases, in order to help promote basic research about the role of mitochondria in innate immunity and provide new strategies for developing mitochondria-targeting drugs.

 

Keywords: Mitochondrial stress, Mitochondrial DNA, Innate immunity, cGAS-STING signaling, STING

 

ROGER A J， MUNOZ-GOMEZ S A， KAMIKAWA R. The origin and diversification of mitochondria. Curr Biol，2017，27(21): R1177–R1192.

WEST A P， SHADEL G S， GHOSH S. Mitochondria in innate immune responses. Nat Rev Immunol，2011，11(6): 389–402.

YOULE R J， VAN DER BLIEK A M. Mitochondrial fission, fusion, and stress. Science，2012，337(6098): 1062–1065.

BRUBAKER S W， BONHAM K S， ZANONI I， et al. Innate immune pattern recognition: a cell biological perspective. Annu Rev Immunol， 2015，33: 257–290.

GONG T， LIU L， JIANG W， et al. DAMP-sensing receptors in sterile inflammation and inflammatory diseases. Nat Rev Immunol，2019，20(2): 95–112.

SUN L J， WU J X， DU F H ， et al. Cyclic GMP-AMP synthase is a cytosolic DNA sensor that activates the type I interferon pathway. Science，2012，339(6121): 786–791.

LI X， SHU C， YI G， et al. Cyclic GMP-AMP synthase is activated by double-stranded DNA-induced oligomerization. Immunity，2013，39(6): 1019–1031.

ABLASSER A， GOLDECK M， CAVLAR T， et al. cGAS produces a 2′-5′-linked cyclic dinucleotide second messenger that activates STING. Nature，2013，498(7454): 380–384.

GAO P， ASCANO M， WU Y， et al. Cyclic [G(2′,5′)pA(3′,5′)p] is the metazoan second messenger produced by DNA-activated cyclic GMP-AMP synthase. Cell，2013，153(5): 1094–1107.

ISHIKAWA H， BARBER G N. STING is an endoplasmic reticulum adaptor that facilitates innate immune signalling. Nature，2008， 455(7213): 674–678.

ZHANG C， SHANG G， GUI X， et al. Structural basis of STING binding with and phosphorylation by TBK1. Nature，2019，567(7748): 394–398.

ZHAO B， DU F， XU P， et al. A conserved PLPLRT/SD motif of STING mediates the recruitment and activation of TBK1. Nature，2019， 569(7758): 718–722.

TANAKA Y， CHEN Z J. STING specifies IRF3 phosphorylation by TBK1 in the cytosolic DNA signaling pathway. Sci Signal，2012，5(214): ra20.

MACKENZIE K J， CARROLL P， MARTIN C A， et al. cGAS surveillance of micronuclei links genome instability to innate immunity. Nature， 2017，548(7668): 461–465.

BARNETT K C， CORONAS-SERNA J M， ZHOU W， et al. Phosphoinositide interactions position cGAS at the plasma membrane to ensure efficient distinction between self- and viral DNA. Cell，2019， 176(6): 1432–1446.

LAHAYE X， GENTILI M， SILVIN A， et al. NONO detects the nuclear HIV capsid to promote cGAS-mediated innate immune activation. Cell， 2018，175(2): 488–501.

XIA P， WANG S， YE B， et al. A circular RNA protects dormant hematopoietic stem cells from DNA sensor cGAS-mediated exhaustion. Immunity，2018，48(4): 688–701.

LIU H， ZHANG H， WU X， et al. Nuclear cGAS suppresses DNA repair and promotes tumorigenesis. Nature，2018，563(7729): 131–136.

ZHAO B， XU P， ROWLETT C M， et al. The molecular basis of tight nuclear tethering and inactivation of cGAS. Nature，2020，587(7835): 673–677.

PATHARE G R， DECOUT A， GLUCK S， et al. Structural mechanism of cGAS inhibition by the nucleosome. Nature，2020，587(7835): 668–672.

MICHALSKI S， DE OLIVEIRA MANN C. C， STAFFORD C， et al Structural basis for sequestration and autoinhibition of cGAS by chromatin. Nature，2020，587(7835): 678–682.

VOLKMAN H E， CAMBIER S， GRAY E E， et al. Tight nuclear tethering of cGAS is essential for preventing autoreactivity. eLife，2019，8: e47491[2021-02-09].https://doi.org/10.7554/elife.47491.

KUJIRAI T， ZIERHUT C， TAKIZAWA Y， et al. Structural basis for the inhibition of cGAS by nucleosomes. Science，2020，370(6515): 455–458.

BOYER J A， SPANGLER C J， STRAUSS J D， et al. Structural basis of nucleosome-dependent cGAS inhibition. Science，2020，370(6515): 450–454.

CUI S， YU Q， CHU L， et al. Nuclear cGAS functions non-canonically to enhance antiviral immunity via recruiting methyltransferase Prmt5. Cell Rep，2020，33(10): 108490.

RONGVAUX A， JACKSON R， HARMAN C C， et al. Apoptotic caspases prevent the induction of type I interferons by mitochondrial DNA. Cell，2014，159(7): 1563–1577.

WEST A P， KHOURY-HANOLD W， STARON M， et al. Mitochondrial DNA stress primes the antiviral innate immune response. Nature，2015， 520(7548): 553–557.

WHITE M J， MCARTHUR K， METCALF D， et al. Apoptotic caspases suppress mtDNA-induced STING-mediated type I IFN production. Cell， 2014，159(7): 1549–1562.

SAFFRAN H A， PARE J M， CORCORAN J A， et al. Herpes simplex virus eliminates host mitochondrial DNA. EMBO Rep，2007，8(2): 188–193.