Project description:Adenosine-to-inosine (A-to-I) RNA editing catalyzed by ADAR1 plays essential roles in the regulation of diverse molecular and cellular processes both under physiological conditions and in the disease states, including cancer. However, mechanisms governing the protein abundance and activity of ADAR1, particularly of its constitutively-expressed and ubiquitous form, ADAR1p110, are largely unknown. Here, we report the E3 ubiquitin ligase SMURF2 as an essential positive regulator of ADAR1p110. We show that SMURF2 directly interacts with ADAR1p110, oligo-ubiquitinates it in an E3 ubiquitin ligase-dependent manner, and stabilizes ADAR1p110 expression by reducing its proteolysis through the proteasomal and lysosomal degradation pathways. The ability of SMURF2 to positively regulate ADAR1p110 was observed in different types of human cells and tissues, and in mouse tissues derived from Smurf2 knock-out and wild-type animals. Further investigations uncovered that SMURF2 regulates ADAR1p110 through its ubiquitination on K744 residue. Mutation of K744 to arginine (K744R), which is also linked to several human disorders, abolished SMURF2-mediated protection of ADAR1p110 from the proteolysis and inactivated its RNA editing activity. Additionally, SMURF2 showed a significant impact on ADAR1p110 protein-protein interactions, influencing its stability and functions. Altogether, these findings reveal SMURF2 as a multilayer regulator of ADAR1p110, governing its protein expression, interactions and functions.

Project description:Adenosine-to-inosine (A-to-I) RNA editing catalyzed by ADAR1 plays essential roles in the regulation of diverse molecular and cellular processes both under physiological conditions and in the disease states, including cancer. However, mechanisms governing the protein abundance and activity of ADAR1, particularly of its constitutively-expressed and ubiquitous form, ADAR1p110, are largely unknown. Here, we report the E3 ubiquitin ligase SMURF2 as an essential positive regulator of ADAR1p110. We show that SMURF2 directly interacts with ADAR1p110, oligo-ubiquitinates it in an E3 ubiquitin ligase-dependent manner, and stabilizes ADAR1p110 expression by reducing its proteolysis through the proteasomal and lysosomal degradation pathways. The ability of SMURF2 to positively regulate ADAR1p110 was observed in different types of human cells and tissues, and in mouse tissues derived from Smurf2 knock-out and wild-type animals. Further investigations uncovered that SMURF2 regulates ADAR1p110 through its ubiquitination on K744 residue. Mutation of K744 to arginine (K744R), which is also linked to several human disorders, abolished SMURF2-mediated protection of ADAR1p110 from the proteolysis and inactivated its RNA editing activity. Additionally, SMURF2 showed a significant impact on ADAR1p110 protein-protein interactions, influencing its stability and functions. Altogether, these findings reveal SMURF2 as a multilayer regulator of ADAR1p110, governing its protein expression, interactions and functions.

Project description:In response to DNA double strand breaks (DSBs), the ATM kinase activates NF-κB factors to stimulate gene expression changes that promote survival and allow time for cells to repair damage. In cell lines, ATM can activate NF-κB transcription factors via two independent, convergent mechanisms. One is ATM-mediated phosphorylation of nuclear NF-κB essential modulator (Nemo) protein, which leads to monoubiquitylation and export of Nemo to the cytoplasm where it engages the IκB kinase (IKK) complex to activate NF-κB. Another is DSB-triggered migration of ATM into the cytoplasm where it promotes monoubiquitylation of Nemo and resulting IKK-mediated activation of NF-κB. ATM has many other functions in the DSB response beyond activation of NF-κB, and Nemo activates NF-κB downstream of diverse stimuli, including developmental or proinflammatory stimuli such as lipopolysaccharides (LPS). To elucidate the in vivo role of DSB-induced, ATM-dependent changes in expression of NF-κB-responsive genes, we generated mice expressing phosphomutant Nemo protein lacking consensus SQ sites for phosphorylation by ATM or related kinases. We demonstrate that these mice are viable/healthy, fertile, and exhibit overall normal B and T lymphocyte development. Moreover, treatment of their B lineage cells with LPS induces normal NF-κB-regulated gene expression changes. Furthermore, in marked contrast to results from a pre-B cell line, primary B lineage cells expressing phosphomutant Nemo treated with the genotoxic drug etoposide induce normal ATM- and Nemo-dependent changes in expression of NF-κB-regulated genes. Our data demonstrate that ATM-dependent phosphorylation of Nemo SQ motifs in vivo is dispensable for DSB-signaled changes in expression of NF-κB-regulated genes.

Project description:DNA Double Strand Breaks (DSBs) repair is essential to safeguard genome integrity but little is known about the contribution of chromosome folding into these processes. Here we unveiled basic principles of chromosome dynamics occurring post-DSB both locally and at a genome wide scale in mammalian cells. We report that topologically associating domains (TAD) that experience a DSB undergo acute ATM-dependent but DNAPK- independent changes. Within these damaged TADs, DSB-induced loop extrusion ensures local transcriptional regulation in response to DSBs. Damaged TADs further coalesce in an ATM-dependent manner, forming a new “D” compartment, where upregulated genes of the DNA damage response (DDR) physically localize suggesting a function of DSB clustering in activating the DNA damage Response. However, these alterations of chromosome folding induced by DSB also come at the expense of an increased translocations rate. Our work highlights the critical impact of chromosome conformation in the maintenance of genome integrity.

Project description:DNA Double-Strand Breaks (DSBs) are highly detrimental since they can lead to mutations and chromosomes rearrangements (amplification, deletion, translocation and chromosome loss). Here, we set to assess the tridimensional genome organization around DSBs and its role in DSB repair foci formation. We performed Hi-C experiments before and after DSB induction and upon ctrl or SCC1 depletion, 4C-seq experiments before and after DSB induction and upon cohesin (SCC1) depletion or ATM inhibition. We also performed ChIP-seq of pATM(S1981), CTCF, P-SMC3(S1083), MDC1 and a calibrated ChIP-seq of SCC1 with or without damage. ChIP-chip of SMC3 (S1083) and SMC1 (S966) were used to show the recruitment of these marks on DNA repair foci. ChIP-chip of gammaH2AX was realized upon SCC1 depletion and ChIP-seq of gammaH2AX was realized upon SCC1 or WAPL to show the role of the cohesin complex in gammaH2AX foci formation. ChIP-seq of gammaH2AX was realized upon ATM or ATR inhibition to show that ATM is the major kinase that phosphorylates H2AX at clean breaks in human cells.

Project description:An E3 ubiquitin ligase Smurf2 and transcriptional co-repressor KAP1 have been documented to play crucial roles in similar cellular pathways including cell cycle, DNA damage response, chromatin compaction, senescence and cell death. Smurf2 and KAP1, through regulation of these cellular processes either drive or suppress tumorigenesis. Studies till date confer Smurf2 with a dual role in carcinogenesis, an oncogene and a tumor suppressor, depending on the cellular context. However, the molecular mechanisms governing Smurf2 functions remain unclear. Furthermore, studies have demonstrated significantly altered KAP1 protein levels in many human malignancies, despite which, the mechanisms operating in and regulating KAP1 stability and activity are obscure. In this study, we obtained evidence which indicates a strong and dynamic association between Smurf2 and KAP1. We found that Smurf2 directly binds KAP1 through its C2, WW1 and HECT domains. Further mechanistic studies also revealed that Smurf2 multi(mono)ubiquitinates KAP1 in E3 ligase-dependent manner. Moreover, Smurf2 differentially alters KAP1 protein levels in different types of mammalian and cancer cells and tissues, and significantly alters KAP1 interactome. Based on these findings, we propose a mechanism to explain the dual role and differential regulation of Smurf2 on KAP1 in a cell-context dependent manner. Further investigations of the identified Smurf2/KAP1 module could potentially lead to development of new, more efficient diagnostics tools and treatment paradigms.

Project description:ATM gene mutation carriers are predisposed to estrogen receptor (ER)-positive breast cancer (BC). ATM prevents BC oncogenesis by activating p53 in every cell; however, much remains unknown about tissue-specific oncogenesis following ATM loss. Here, we report that ATM controls the early transcriptional response to estrogens. This response depends on topoisomerase II (TOP2), which generates TOP2-DNA double-strand break (DSB) complexes and rejoins the breaks. When TOP2-mediated ligation fails, ATM facilitates DSB repair. Following estrogen exposure, TOP2-dependent DSBs arise at the c-MYC enhancer in human BC cells, and their defective repair changes the activation profile of enhancers and induces the overexpression of many genes including the c-MYC oncogene. CRISPR/Cas9 cleavage at the enhancer also causes c-MYC overexpression, indicating that this DSB causes c-MYC overexpression. Estrogen treatment induced c-Myc protein overexpression in mammary epithelial cells of ATM-deficient mice. In conclusion, ATM suppresses the c-Myc-driven proliferative effects of estrogens, possibly explaining such tissue-specific oncogenesis.

Project description:The DNA damage response (DDR) is an extensive signaling network that is robustly mobilized by DNA double-strand breaks (DSBs). The primary transducer of the DSB response is the protein kinase, ataxia-telangiectasia, mutated (ATM). Here, we establish nuclear poly(A)-binding protein 1 (PABPN1) as a novel target of ATM and a crucial player in the DSB response. PABPN1 usually functions in regulation of RNA processing and stability. We establish that PABPN1 is recruited to the DDR as a critical regulator of DSB repair. A portion of PABPN1 relocalizes to DSB sites and is phosphorylated on Ser95 in an ATM-dependent manner. PABPN1 depletion sensitizes cells to DSBinducing agents and prolongs the DSB-induced G2/M cell-cycle arrest, and DSB repair is hampered by PABPN1 depletion or elimination of its phosphorylation site. PABPN1 is required for optimal DSB repair via both nonhomologous end-joining (NHEJ) and homologous recombination repair (HRR), and specifically is essential for efficient DNAend resection, an initial, key step in HRR. Using mass spectrometry analysis, we capture DNA damage-induced interactions of phospho-PABPN1, including well-established DDR players as well as other RNA metabolizing proteins. Our results uncover a novel ATM-dependent axis in the rapidly growing interface between RNA metabolism and the DDR.

Project description:We previously reported that differential protein degradation of TKI-sensitive [L858R, del(E746-A750)] and resistant (T790M) epidermal growth factor receptor (EGFR) mutants upon erlotinib treatment correlates with drug sensitivity. However, the molecular mechanism remains unclear. We also reported SMAD ubiquitination regulatory factor 2 (SMURF2) as a stabilizer of EGFR in a ligase (E3) activity-dependent manner. Here, using in vitro and in vivo ubiquitination assays, mass spectrometry, and super-resolution microscopy, we show SMURF2-EGFR functional interaction is critical in receptor stability and TKI sensitivity. We found that L858R/T790M EGFR is a preferred substrate of SMURF2-UBCH5 (an E3-E2) complex-mediated K63-linked polyubiquitination, which preferentially stabilizes mutant receptor. We identified three lysine (K) residues (K721, 1037 and 1164) as the sites of ubiquitination and replacement of K to acetylation-mimicking asparagine (Q) at K1037 position in L858R/T790M background converts the stable protein sensitive to erlotinib-induced degradation. Using STochastic Optical Reconstruction Microscopy (STORM) imaging, we show that SMURF2 presence allows longer membrane retention of activated EGFR upon EGF treatment, whereas, siRNA-mediated SMURF2 knockdown fastens receptor endocytosis and lysosome enrichment. In an erlotinib-sensitive PC9 cells, SMURF2 overexpression increased EGFR levels with improved erlotinib tolerance, whereas, SMURF2 knockdown decreased EGFR steady state levels in NCI-H1975 and PC9-AR cells to overcome erlotinib and AZD-9291 resistance respectively. Additionally, disruption of the SMURF2-UBCH5 complex destabilized EGFR. Together, we propose that SMURF2-mediated preferential polyubiquitination of L858R/T790M EGFR may be competing with acetylation-mediated receptor internalization to provide enhanced receptor stability and that disruption of the E3-E2 complex may be an attractive alternate to overcome TKI resistance

Project description:The ubiquitin-proteasome system (UPS) plays a crucial role in cellular homeostasis, but the mechanistic aspects of its involvement in the DNA damage response (DDR) remain largely elusive. Here, we identify a homozygous truncation mutation in the UBQLN4 gene in families with highly pleiotropic autosomal recessive syndrome, with clinical and cellular characteristics reminiscent of DNA repair disorders. UBQLN4 loss leads to hypersensitivity to genotoxic stress and delayed repair of DNA double-strand breaks (DSBs). By dissecting the molecular mechanism of action, we find an ATM-dependent phosphorylation site on UBQLN4 (Ser-318), which is required for the cellular protection against DNA damage and proper DSB repair. UBQLN4 is a known proteasomal shuttle factor for ubiquitinated proteins and we demonstrate that loss of UBQLN4 leads to the accumulation and retention of MRE11 and RPA70 at DSB sites. Concomitantly, we find that UBQLN4 loss of function is associated with a relative increase in homologous recombination-mediated DSB repair and a reduced usage of non-homologous end joining. In contrast, UBQLN4 overexpression represses HRR usage. We show that this UBQLN4-driven preference for NHEJ-mediated DSB repair is conserved in C. elegans. Moreover, a detailed analysis of human neuroblastoma and melanoma cancer samples reveals that UBQLN4 is overexpressed in aggressive tumors. In line with a HRR defect, we observe that tumor cells overexpressing UBQLN4 display an actionable PARP1 inhibitor sensitivity. Thus, we identify a novel DDR component, which may be a promising target for PARP1 inhibition in aggressive cancer.