Project description:The non-homologous end-joining (NHEJ) pathway is critical for DNA double-strand break repair and is essential for lymphocyte development and maturation. The Ku70/Ku80 heterodimer (KU) binds to DNA ends, initiating NHEJ and recruiting additional factors, including DNA-dependent protein kinase catalytic subunit (DNA-PKcs) that caps the ends and pushes KU inward. The C-terminus of Ku70 in higher eukaryotes includes a flexible linker and a SAP domain, whose physiological role remains poorly understood. To investigate this, we generated a mouse model with knock-in deletion of the SAP domain (Ku70DSAP/DSAP). Ku70DSAP supports KU stability and its recruitment to DNA damage sites in vivo. In contrast to the growth retardation and immunodeficiency seen in Ku70-/- mice, Ku70DSAP/DSAP mice show no defects in lymphocyte development and maturation. Structural modeling of KU on long dsDNA, but not dsRNA suggests that the SAP domain can bind to an adjacent major groove, where it can limit KU’s rotation and lateral movement along the dsDNA. Consistent with this model, in the absence of DNA-PKcs that caps the ends, Ku70DSAP fails to support stable DNA damage-induced KU foci. In DNA-PKcs-/- mice, Ku70DSAP abrogates the leaky T cell development and reduces both the qualitative and quantitative aspects of residual V(D)J recombination. Moreover, purified Ku70DSAP also has reduced affinity for DNA ends and dissociates more readily. These findings revealed a physiological role of the SAP domain in NHEJ by restricting KU rotation and lateral movement on DNA that is largely masked by DNA-PKcs.

Project description:Classical nonhomologous end-joining (C-NHEJ) repairs DNA double-stranded breaks (DSBs) throughout interphase but is thought to predominate in G1-phase when homologous recombination is unavailable. Complexes containing the Ku70/80 ("Ku") and XRCC4/Ligase IV (Lig4) core C-NHEJ factors are required, respectively, for sensing and joining DSBs. While such factors are exclusively required for joining RAG1/2-initiated DSBs during V(D)J recombination in G1-phase lymphocyte progenitors, cycling cells deficient for core C-NHEJ factors join chromosomal DSBs by alternative end-joining (A-EJ) pathways. Restriction of V(D)J recombination to C-NHEJ has been attributed to RAG-mediated exclusion of A-EJ; however, it remains unclear whether A-EJ is similarly excluded from more general DSBs in G1. Here, we report that Ku actively and robustly suppresses A-EJ of RAG1/2 and two classes of engineered endonuclease-mediated DSBs in G1-arrested progenitor B cell lines. Thus, while targeted DSBs remain as free broken ends in Lig4-deficient G1-arrested progenitor B cells, deletion of Ku70 in Lig4-deficient cells restores DSB rejoining and translocation to levels observed in Ku70-deficient counterparts. Correspondingly, while V(D)J recombination is abrogated in Ligase4-deficient lines, V(D)J-like joining occurs in Ku70-deficient and Ku70/Lig4 double-deficient lines through a translocation-based A-EJ mechanism. We conclude that in G1, Lig4-deficient progenitor B cells are functionally end-joining deficient due to a near complete Ku-dependent block in A-EJ. Thus, the differential impacts of Ku deficiency versus XRCC4/Ligase IV deficiency on V(D)J recombination, severity of neuronal apoptosis, and embryonic development, including Ku-deficiency rescuing Lig4-deficient embryonic lethality, may be explained by Ku-mediated inhibition of A-EJ in the G1 cell cycle phase.

Project description:Aberrant activation of innate immune receptors can cause a spectrum of immune disorders, such as Aicardi-Goutières syndrome (AGS). One such receptor is MDA5, a viral double-stranded RNA (dsRNA) sensor that induces antiviral immune response. We here demonstrate that constitutive activation of MDA5 in AGS results from the loss of tolerance to cellular dsRNAs formed by Alu retroelements. While wild-type MDA5 cannot efficiently recognize Alu-dsRNA because its filament formation on dsRNA is impaired by the imperfect duplex structure, AGS-variants of MDA5 display reduced sensitivity to duplex structural irregularities, assembling signaling-competent filaments on Alu-dsRNA. Moreover, we identified an unexpected role of RNA-rich cellular environment in suppressing aberrant MDA5 oligomerization, highlighting context-dependence of self vs. non-self discrimination. Overall, our work demonstrates that the increased efficiency of MDA5 to recognize dsRNA comes at a cost of self-recognition, and implicates a unique role of Alu RNAs as virus-like elements that shape the primate immune system.

Project description:Aberrant activation of innate immune receptors can cause a spectrum of immune disorders, such as Aicardi-Goutières syndrome (AGS). One such receptor is MDA5, a viral double-stranded RNA (dsRNA) sensor that induces antiviral immune response. We here demonstrate that constitutive activation of MDA5 in AGS results from the loss of tolerance to cellular dsRNAs formed by Alu retroelements. While wild-type MDA5 cannot efficiently recognize Alu-dsRNA because its filament formation on dsRNA is impaired by the imperfect duplex structure, AGS-variants of MDA5 display reduced sensitivity to duplex structural irregularities, assembling signaling-competent filaments on Alu-dsRNA. Moreover, we identified an unexpected role of RNA-rich cellular environment in suppressing aberrant MDA5 oligomerization, highlighting context-dependence of self vs. non-self discrimination. Overall, our work demonstrates that the increased efficiency of MDA5 to recognize dsRNA comes at a cost of self-recognition, and implicates a unique role of Alu RNAs as virus-like elements that shape the primate immune system.

Project description:DNA-PKcs is a critical component of the non-homologous end joining (NHEJ) pathway, playing a role in the re-ligation of DNA double-strand breaks (DSBs) generated by RAG1/2 during V(D)J recombination in antigen loci. When NHEJ is deficient, DSBs can be repaired through alternative end joining (A-EJ). In this study, we investigated the consequences of DNA-PKcs deletion on V-J recombination at the IgK antigen locus. Our results reveal that DNA-PKcs deletion leads to inefficient V-J recombination, exhibiting phenotypes such as reduced efficiency, increased end resection, and decreased micro-insertions in the repair pattern. These findings are consistent with previously reported functions of Ku70, another key player in NHEJ. However, unlike Ku70, additional deletion of DNA-PKcs does not restore the efficiency of repair in the absence of Lig4. Instead, it reduces both end resection and microhomology-mediated repair. These observations highlight the context-dependent role of DNA-PKcs in end processing. The presence or absence of Lig4 appears to influence the function of DNA-PKcs, further emphasizing the intricate interplay between repair factors in the DNA damage response. Overall, our findings provide insights into the distinct functions of DNA-PKcs and Ku70 in V(D)J recombination and underscore the complex regulatory mechanisms underlying repair efficiency in different genetic backgrounds.

Project description:The antiviral defense in vertebrates requires the innate immune system to sense foreign “non-self” nucleic acids while avoiding “self” nucleic acids, which is accomplished by an intricate system. Cellular double-stranded RNAs (dsRNAs) are edited by the RNA editing enzyme ADAR1 to prevent their dsRNA structure pattern from being recognized as viral dsRNA. Lack of RNA editing by ADAR1 enables activation of MDA5, a cytosolic dsRNA sensor, by cellular dsRNA. Additional RNA editing- independent functions of ADAR1 have been proposed, but the specific mechanism remains elusive. Here we demonstrate that RNA binding by ADAR1, independent of its editing activity, restricts the activation of PKR, another cytosolic dsRNA sensor, by cellular dsRNA. Mechanistically, the loss of ADAR1 editing caused MDA5 activation to induce interferon signaling, while a lack of ADAR1 protein or its dsRNA binding ability led to PKR activation, with subsequent stress granule formation and proliferation arrest. Based on these findings we rescued the Adar1−/− mice from embryonic lethality to adulthood by deleting both MDA5 and PKR, in contrast to the limited rescue of Adar1−/− mice by removing MDA5 or PKR alone. Our findings reveal a multifaceted contribution of ADAR1 in regulating the immunogenicity of “self” dsRNAs. Furthermore, ADAR1 is an immuno-oncology target for drug development, and the separation of ADAR1’s RNA editing and binding functions provides mechanistic insights for such developments. 

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact.

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact.

Project description:Protein kinase R (PKR), an innate immune sensor for double-stranded RNA (dsRNA), is critical for antiviral defense, but its aberrant activation by cellular dsRNA is linked to various diseases. The dsRNA-binding protein PACT plays a crucial and controversial role in the PKR pathway. We demonstrate that PACT is an essential negative regulator of PKR against endogenous dsRNA ligands like inverted repeat Alu RNAs, which satisfy PKR’s selectivity for long dsRNA and robustly activate PKR in the absence of PACT. PACT employs an unusual inhibitory mechanism sensitive to dsRNA length and concentration, inhibiting PKR through low-affinity interactions most effective when both are bound to the same dsRNA molecule. Consequently, PACT’s inhibition of PKR is more robust when dsRNA is longer and less abundant, with minimal effect on abundant or short dsRNA. Thus, PACT functions as a rheostat, setting the PKR activation threshold for long endogenous dsRNA without altering its inherent activity.

Project description:The non-homologous end-joining (NHEJ) pathway is a major DNA double-strand break repair pathway in mammals and is essential for lymphocyte development. Ku70 and Ku80 heterodimer (KU) initiates NHEJ, thereby recruiting and activating the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs). While DNA-PKcs deletion only moderately impairs end-ligation, the expression of Kinase-dead DNA-PKcs completely abrogates NHEJ. Active DNA-PK phosphorylates DNA-PKcs at two clusters – PQR around S2056 (S2053 in mouse) and ABCDE around T2609. Alanine substitution at the S2056 cluster moderately compromises end-ligation on plasmid-based assays. But mice carrying alanine substitution at all 5 serine residues within the S2056 cluster (DNA-PKcsPQR/PQR) display no defect in lymphocyte development, leaving the physiological significance of S2056 cluster phosphorylation elusive. XLF is a non-essential NHEJ factor. Xlf-/- mice have substantial peripheral lymphocytes that are completely abolished by the loss of DNA-PKcs, the related ATM kinases, other chromatin associated DNA damage response factors (e.g., 53BP1, MDC1, H2AX, MRI, etc.) or RAG2-C-terminal regions, suggesting functional redundancy. While ATM inhibition does not further compromise end-ligation, here we show that in XLF-deficient background, DNA-PKcs S2056 cluster phosphorylation is critical for normal lymphocyte development. Chromosomal V(D)J recombination from DNA-PKcsPQR/PQRXlf-/- B cells is efficient but often has large deletions that jeopardize lymphocyte development. Class switch recombination junctions from DNA-PKcsPQR/PQRXlf-/- mice are less efficient and the residual junctions display decreased fidelity and increased deletion. These findings establish a role for DNA-PKcs S2056 cluster phosphorylation in physiological chromosomal NHEJ, implying that S2056 cluster phosphorylation contributes to the synergy between XLF and DNA-PKcs in end-ligation.