NUDCD3 deficiency disrupts V(D)J recombination to cause SCID and Omenn syndrome.

Inborn errors of T cell development present a pediatric emergency in which timely curative therapy is informed by molecular diagnosis. In 11 affected patients across four consanguineous kindreds, we detected homozygosity for a single deleterious missense variant in the gene NudC domain-containing 3 (NUDCD3). Two infants had severe combined immunodeficiency with the complete absence of T and B cells (T -B- SCID), whereas nine showed classical features of Omenn syndrome (OS). Restricted antigen receptor gene usage by residual T lymphocytes suggested impaired V(D)J recombination. Patient cells showed reduced expression of NUDCD3 protein and diminished ability to support RAG-mediated recombination in vitro, which was associated with pathologic sequestration of RAG1 in the nucleoli. Although impaired V(D)J recombination in a mouse model bearing the homologous variant led to milder immunologic abnormalities, NUDCD3 is absolutely required for healthy T and B cell development in humans.

Divergent Molecular and Cellular Responses to Low and High-Dose Ionizing Radiation.

Cancer risk after ionizing radiation (IR) is assumed to be linear with the dose; however, for low doses, definite evidence is lacking. Here, using temporal multi-omic systems analyses after a low (LD; 0.1 Gy) or a high (HD; 1 Gy) dose of X-rays, we show that, although the DNA damage response (DDR) displayed dose proportionality, many other molecular and cellular responses did not. Phosphoproteomics uncovered a novel mode of phospho-signaling via S12-PPP1R7, and large-scale dephosphorylation events that regulate mitotic exit control in undamaged cells and the G2/M checkpoint upon IR in a dose-dependent manner. The phosphoproteomics of irradiated DNA double-strand breaks (DSBs) repair-deficient cells unveiled extended phospho-signaling duration in either a dose-dependent (DDR signaling) or independent (mTOR-ERK-MAPK signaling) manner without affecting signal magnitude. Nascent transcriptomics revealed the transcriptional activation of genes involved in NRF2-regulated antioxidant defense, redox-sensitive ERK-MAPK signaling, glycolysis and mitochondrial function after LD, suggesting a prominent role for reactive oxygen species (ROS) in molecular and cellular responses to LD exposure, whereas DDR genes were prominently activated after HD. However, how and to what extent the observed dose-dependent differences in molecular and cellular responses may impact cancer development remain unclear, as the induction of chromosomal damage was found to be dose-proportional (10-200 mGy).

PBAF loss leads to DNA damage-induced inflammatory signaling through defective G2/M checkpoint maintenance.

The PBRM1 subunit of the PBAF (SWI/SNF) chromatin remodeling complex is mutated in ∼40% of clear cell renal cancers. PBRM1 loss has been implicated in responses to immunotherapy in renal cancer, but the mechanism is unclear. DNA damage-induced inflammatory signaling is an important factor determining immunotherapy response. This response is kept in check by the G2/M checkpoint, which prevents progression through mitosis with unrepaired damage. We found that in the absence of PBRM1, p53-dependent p21 up-regulation is delayed after DNA damage, leading to defective transcriptional repression by the DREAM complex and premature entry into mitosis. Consequently, DNA damage-induced inflammatory signaling pathways are activated by cytosolic DNA. Notably, p53 is infrequently mutated in renal cancer, so PBRM1 mutational status is critical to G2/M checkpoint maintenance. Moreover, we found that the ability of PBRM1 deficiency to predict response to immunotherapy correlates with expression of the cytosolic DNA-sensing pathway in clinical samples. These findings have implications for therapeutic responses in renal cancer.

ATM's Role in the Repair of DNA Double-Strand Breaks.

Ataxia telangiectasia mutated (ATM) is a central kinase that activates an extensive network of responses to cellular stress via a signaling role. ATM is activated by DNA double strand breaks (DSBs) and by oxidative stress, subsequently phosphorylating a plethora of target proteins. In the last several decades, newly developed molecular biological techniques have uncovered multiple roles of ATM in response to DNA damage-e.g., DSB repair, cell cycle checkpoint arrest, apoptosis, and transcription arrest. Combinational dysfunction of these stress responses impairs the accuracy of repair, consequently leading to dramatic sensitivity to ionizing radiation (IR) in ataxia telangiectasia (A-T) cells. In this review, we summarize the roles of ATM that focus on DSB repair.

TP53 modulates radiotherapy fraction size sensitivity in normal and malignant cells.

Recent clinical trials in breast and prostate cancer have established that fewer, larger daily doses (fractions) of radiotherapy are safe and effective, but these do not represent personalised dosing on a patient-by-patient basis. Understanding cell and molecular mechanisms determining fraction size sensitivity is essential to fully exploit this therapeutic variable for patient benefit. The hypothesis under test in this study is that fraction size sensitivity is dependent on the presence of wild-type (WT) p53 and intact non-homologous end-joining (NHEJ). Using single or split-doses of radiation in a range of normal and malignant cells, split-dose recovery was determined using colony-survival assays. Both normal and tumour cells with WT p53 demonstrated significant split-dose recovery, whereas Li-Fraumeni fibroblasts and tumour cells with defective G1/S checkpoint had a large S/G2 component and lost the sparing effect of smaller fractions. There was lack of split-dose recovery in NHEJ-deficient cells and DNA-PKcs inhibitor increased sensitivity to split-doses in glioma cells. Furthermore, siRNA knockdown of p53 in fibroblasts reduced split-dose recovery. In summary, cells defective in p53 are less sensitive to radiotherapy fraction size and lack of split-dose recovery in DNA ligase IV and DNA-PKcs mutant cells suggests the dependence of fraction size sensitivity on intact NHEJ.

Roles for 53BP1 in the repair of radiation-induced DNA double strand breaks.

In mammalian cells, the mediator protein, 53BP1, exerts distinct impacts on the repair of DNA double strand breaks (DSBs) depending on the setting, for example whether the DSBs arise at telomeres or during replication or class switch recombination. Here, we focus on two roles of 53BP1 in response to ionising radiation (IR)-induced DSBs (IR-DSBs). Canonical DNA non-homologous end-joining (c-NHEJ) is the major DSB repair pathway with homologous recombination (HR) contributing to DSB repair in S/G2 phase. ATM signalling promotes histone modifications and protein assembly in the DSB vicinity, which can be visualised as irradiation induced foci (IRIF). 53BP1 assembles at DSBs in a complex manner involving the formation of nano-domains. In G1 and G2 phase, X- or gamma-ray induced DSBs are repaired with biphasic kinetics. 70-80 % of DSBs are repaired with fast kinetics in both cell cycle phases by c-NHEJ; the remaining DSBs are repaired with slower kinetics in G2 phase via HR and in G1 by a specialised form of c-NHEJ termed Artemis and resection-dependent c-NHEJ, due to a specific requirement for the nuclease, Artemis and resection factors. 53BP1 is essential for the repair of DSBs rejoined with slow kinetics in G1 and G2 phase. This 53BP1 function requires its tandem BRCT domain and interaction with NBS1. As a distinct function, 53BP1 suppresses resection during both HR and Artemis and resection-dependent c-NHEJ. This latter role requires RIF1 and is counteracted by BRCA1. 53BP1 appears to be dispensable for the rejoining of the fast c-NHEJ repair process.

Roles for the DNA-PK complex and 53BP1 in protecting ends from resection during DNA double-strand break repair.

p53-binding protein 1 (53BP1) exerts distinct impacts in different situations involving DNA double-strand break (DSB) rejoining. Here we focus on how 53BP1 impacts upon the repair of ionising radiation-induced DSBs (IR-DSBs) and how it interfaces with Ku, the DNA end-binding component of canonical non-homologous end-joining (c-NHEJ), the major DSB repair pathway in mammalian cells. We delineate three forms of IR-DSB repair: resection-independent c-NHEJ, which rejoins most IR-DSBs with fast kinetics in G1 and G2, and Artemis and resection-dependent c-NHEJ and homologous recombination (HR), which repair IR-DSBs with slow kinetics in G1 and G2 phase, respectively. The fast component of DSB repair after X-ray exposure occurs via c-NHEJ with normal kinetics in the absence of 53BP1. Ku is highly abundant and has avid DNA end-binding capacity which restricts DNA end-resection and promotes resection-independent c-NHEJ at most IR-DSBs. Thus, 53BP1 is largely dispensable for resection-independent c-NHEJ. In contrast, 53BP1 is essential for the process of rejoining IR-DSBs with slow kinetics. This role requires 53BP1's breast cancer susceptibility gene I (BRCA1) C-terminal (BRCT) 2 domain, persistent ataxia telangiectasia mutated (ATM) activation and potentially relaxation of compacted chromatin at heterochromatic-DSBs. In distinction, 53BP1 inhibits resection-dependent IR-DSB repair in G1 and G2, and this resection-inhibitory function can be counteracted by BRCA1. We discuss a model whereby most IR-DSBs are rapidly repaired by 53BP1-independent and resection-independent c-NHEJ due to the ability of Ku to inhibit resection, but, if delayed, then resection in the presence of Ku is triggered, the 53BP1 barrier comes into force and BRCA1 counteraction is required for resection.

Canonical DNA non-homologous end-joining; capacity versus fidelity.

The significance of canonical DNA non-homologous end-joining (c-NHEJ) for DNA double strand break (DSB) repair has increased from lower organisms to higher eukaryotes, and plays the predominant role in human cells. Ku, the c-NHEJ end-binding component, binds DSBs with high efficiency enabling c-NHEJ to be the first choice DSB repair pathway, although alternative pathways can ensue after regulated steps to remove Ku. Indeed, radiation-induced DSBs are repaired rapidly in human cells. However, an important question is the fidelity with which radiation-induced DSBs are repaired, which is essential for assessing any harmful impacts caused by radiation exposure. Indeed, is compromised fidelity a price we pay for high capacity repair. Two subpathways of c-NHEJ have been revealed; a fast process that does not require nucleases or significant chromatin changes and a slower process that necessitates resection factors, and potentially more significant chromatin changes at the DSB. Recent studies have also shown that DSBs within transcriptionally active regions are repaired by specialised mechanisms, and the response at such DSBs encompasses a process of transcriptional arrest. Here, we consider the limitations of c-NHEJ that might result in DSB misrepair. We consider the common IR-induced misrepair events and discuss how they might arise via the distinct subpathways of c-NHEJ.

Meeting report on ICRR2019, the 16th International Congress on Radiation Research.

The 16th International Congress of Radiation Research (ICRR2019) was held in Manchester, UK, in August 2019. The Congress, which is held every four years, covered a wide spectrum of topics relevant for all aspects of radiation research including basic mechanisms, translational research, radiotherapy and health effects, and ecology. Here, we provide a report of the plenary and keynote talks presented at the meeting.

Regulation of programmed death-ligand 1 expression in response to DNA damage in cancer cells: Implications for precision medicine.

Anti-programmed death-1 (PD-1)/programmed death-ligand 1 (PD-L1) therapy, which is one of the most promising cancer therapies, is licensed for treating various tumors. Programmed death-ligand 1, which is expressed on the surface of cancer cells, leads to the inhibition of T lymphocyte activation and immune evasion if it binds to the receptor PD-1 on CTLs. Anti-PD-1/PD-L1 Abs inhibit interactions between PD-1 and PD-L1 to restore antitumor immunity. Although certain patients achieve effective responses to anti-PD-1/PD-L1 therapy, the efficacy of treatment is highly variable. Clinical trials of anti-PD-1/PD-L1 therapy combined with radiotherapy/chemotherapy are underway with suggestive evidence of favorable outcome; however, the molecular mechanism is largely unknown. Among several molecular targets that can influence the efficacy of anti-PD-1/PD-L1 therapy, PD-L1 expression in tumors is considered to be a critical biomarker because there is a positive correlation between the efficacy of combined treatment protocols and PD-L1 expression levels. Therefore, understanding the mechanisms underlying the regulation of PD-L1 expression in cancer cells, particularly the mechanism of PD-L1 expression following DNA damage, is important. In this review, we consider recent findings on the regulation of PD-L1 expression in response to DNA damage signaling in cancer cells.