A conserved isoleucine in the binding pocket of RIG-I controls immune tolerance to mitochondrial RNA

RIG-I is a cytosolic receptor of viral RNA essential for the immune response to numerous RNA viruses. Accordingly, RIG-I must sensitively detect viral RNA yet tolerate abundant self-RNA species. The basic binding cleft and an aromatic amino acid of the RIG-I C-terminal domain(CTD) mediate high-affinity recognition of 5’triphosphorylated and 5’base-paired RNA(dsRNA). Here, we found that, while 5’unmodified hydroxyl(OH)-dsRNA demonstrated residual activation potential, 5’-monophosphate(5’p)-termini, present on most cellular RNAs, prevented RIG-I activation. Determination of CTD/dsRNA co-crystal structures and mutant activation studies revealed that the evolutionarily conserved I875 within the CTD sterically inhibits 5’p-dsRNA binding. RIG-I(I875A) was activated by both synthetic 5’p-dsRNA and endogenous long dsRNA within the polyA-rich fraction of total cellular RNA. RIG-I(I875A) specifically interacted with a long, highly structured, polyA-bearing, non-coding mitochondrial(mt) RNA, and depletion of mtRNA from total RNA abolished its activation. Altogether, our study demonstrates that avoidance of 5’p-RNA recognition is crucial to preventing mtRNA-triggered RIG-I-mediated autoinflammation.

[1]  J. Rehwinkel,et al.  Adenosine-to-inosine editing of endogenous Z-form RNA by the deaminase ADAR1 prevents spontaneous MAVS-dependent type I interferon responses , 2021, Immunity.

[2]  G. Hartmann,et al.  Immune Sensing Mechanisms that Discriminate Self from Altered Self and Foreign Nucleic Acids , 2020, Immunity.

[3]  J. Rehwinkel,et al.  RIG-I-like receptors: their regulation and roles in RNA sensing , 2020, Nature Reviews Immunology.

[4]  Christopher J. Williams,et al.  Macromolecular structure determination using X-rays, neutrons and electrons: recent developments in Phenix , 2019, Acta crystallographica. Section D, Structural biology.

[5]  A. Iwasaki,et al.  RIG-I Selectively Discriminates against 5'-Monophosphate RNA. , 2019, Cell reports.

[6]  L. Brodsky,et al.  Extensive editing of cellular and viral double-stranded RNA structures accounts for innate immunity suppression and the proviral activity of ADAR1p150 , 2018, PLoS biology.

[7]  John Karijolich,et al.  RIG-I like receptor sensing of host RNAs facilitates the cell-intrinsic immune response to KSHV infection , 2018, Nature Communications.

[8]  Smita S. Patel,et al.  RIG-I Uses an ATPase-Powered Translocation-Throttling Mechanism for Kinetic Proofreading of RNAs and Oligomerization. , 2018, Molecular cell.

[9]  Yoosik Kim,et al.  PKR Senses Nuclear and Mitochondrial Signals by Interacting with Endogenous Double-Stranded RNAs. , 2018, Molecular cell.

[10]  A. Munnich,et al.  Mitochondrial double-stranded RNA triggers antiviral signalling in humans , 2018, Nature.

[11]  K. Hopfner,et al.  Unified mechanisms for self-RNA recognition by RIG-I Singleton-Merten syndrome variants , 2018, eLife.

[12]  Cheng-Zhong Zhang,et al.  Breaching Self-Tolerance to Alu Duplex RNA Underlies MDA5-Mediated Inflammation , 2018, Cell.

[13]  Christopher J. Williams,et al.  MolProbity: More and better reference data for improved all‐atom structure validation , 2018, Protein science : a publication of the Protein Society.

[14]  Y. Crow,et al.  Type I interferon–mediated monogenic autoinflammation: The type I interferonopathies, a conceptual overview , 2016, The Journal of experimental medicine.

[15]  G. Hartmann,et al.  Discriminating self from non-self in nucleic acid sensing , 2016, Nature Reviews Immunology.

[16]  R. Lightowlers,et al.  The process of mammalian mitochondrial protein synthesis , 2016, Cell and Tissue Research.

[17]  F. Jiang,et al.  Structural basis for m7G recognition and 2′-O-methyl discrimination in capped RNAs by the innate immune receptor RIG-I , 2016, Proceedings of the National Academy of Sciences.

[18]  Cory C. Funk,et al.  Isoforms of RNA-Editing Enzyme ADAR1 Independently Control Nucleic Acid Sensor MDA5-Driven Autoimmunity and Multi-organ Development. , 2015, Immunity.

[19]  Y. Crow,et al.  The SKIV2L RNA exosome limits activation of the RIG-I-like receptors , 2014, Nature Immunology.

[20]  G. Hartmann,et al.  Antiviral immunity via RIG-I-mediated recognition of RNA bearing 5′-diphosphates , 2014, Nature.

[21]  Roger A. Jones,et al.  Structure-Function Analysis of STING Activation by c[G(2′,5′)pA(3′,5′)p] and Targeting by Antiviral DMXAA , 2013, Cell.

[22]  S. Cusack,et al.  A structure-based model of RIG-I activation. , 2012, RNA.

[23]  W. Rossmanith Of P and Z: Mitochondrial tRNA processing enzymes , 2012, Biochimica et biophysica acta.

[24]  S. Cusack,et al.  Structural Basis for the Activation of Innate Immune Pattern-Recognition Receptor RIG-I by Viral RNA , 2011, Cell.

[25]  L. Kaderali,et al.  Molecular Mechanism of Signal Perception and Integration by the Innate Immune Sensor Retinoic Acid-inducible Gene-I (RIG-I)* , 2011, The Journal of Biological Chemistry.

[26]  C. Kao,et al.  Crystal structure of RIG-I C-terminal domain bound to blunt-ended double-strand RNA without 5′ triphosphate , 2010, Nucleic acids research.

[27]  R. Strong,et al.  The structural basis of 5' triphosphate double-stranded RNA recognition by RIG-I C-terminal domain. , 2010, Structure.

[28]  Osamu Takeuchi,et al.  Recognition of 5' triphosphate by RIG-I helicase requires short blunt double-stranded RNA as contained in panhandle of negative-strand virus. , 2009, Immunity.

[29]  S. Akira,et al.  Length-dependent recognition of double-stranded ribonucleic acids by retinoic acid–inducible gene-I and melanoma differentiation–associated gene 5 , 2008, The Journal of experimental medicine.

[30]  Arnold Martin,et al.  Processing of Genome 5′ Termini as a Strategy of Negative-Strand RNA Viruses to Avoid RIG-I-Dependent Interferon Induction , 2008, PloS one.

[31]  F. Inagaki,et al.  Nonself RNA-sensing mechanism of RIG-I helicase and activation of antiviral immune responses. , 2008, Molecular cell.

[32]  L. Burzio,et al.  Expression of a novel non-coding mitochondrial RNA in human proliferating cells , 2007, Nucleic acids research.

[33]  Gunther Hartmann,et al.  5'-Triphosphate RNA Is the Ligand for RIG-I , 2006, Science.

[34]  Paul A. Serbinowski,et al.  A structural basis for discriminating between self and nonself double-stranded RNAs in mammalian cells , 2006, Nature Biotechnology.

[35]  D. Geiger,et al.  Polyadenylation and Degradation of Human Mitochondrial RNA: the Prokaryotic Past Leaves Its Mark , 2005, Molecular and Cellular Biology.

[36]  S. Akira,et al.  Sequence-specific potent induction of IFN-α by short interfering RNA in plasmacytoid dendritic cells through TLR7 , 2005, Nature Medicine.

[37]  J. Enríquez,et al.  Replication and Transcription of Mammalian Mitochondrial Dna , 2003, Experimental physiology.

[38]  J. Lytle,et al.  Specific Cleavage of Hepatitis C Virus RNA Genome by Human RNase P* , 2002, The Journal of Biological Chemistry.

[39]  Julio Montoya,et al.  tRNA punctuation model of RNA processing in human mitochondria , 1981, Nature.

[40]  V. Hornung,et al.  Enzymatic synthesis and purification of a defined RIG-I ligand. , 2014, Methods in molecular biology.

[41]  M. King,et al.  Isolation of human cell lines lacking mitochondrial DNA. , 1996, Methods in enzymology.