Álvarez-Prado et al. report a detailed map of AID-induced off-target mutations and identify molecular features that predict gene mutability. They identify a novel AID hotspot and demonstrate that base excision and mismatch repair back up each other to repair most AID deamination events.
SUMMARYPARP1 is the main sensor of single- and double-strand breaks in DNA and, in building chains of poly(ADP-ribose), promotes the recruitment of many downstream signaling and effector proteins involved in the DNA damage response (DDR). We show a robust physical interaction between PARP1 and the replication fork protein TIMELESS, distinct from the known TIMELESS-TIPIN complex, which activates the intra-S phase checkpoint. TIMELESS recruitment to laser-induced sites of DNA damage is dependent on its binding to PARP1, but not PARP1 activity. We also find that the PARP1-TIMELESS complex contains a number of established PARP1 substrates, and TIMELESS mutants unable to bind PARP1 are impaired in their ability to bind PARP1 substrates. Further, PARP1 binding to certain substrates and their recruitment to DNA damage lesions is impaired by TIMELESS knockdown, and TIMELESS silencing significantly impairs DNA double-strand break repair. We hypothesize that TIMELESS cooperates in the PARP1-mediated DDR.
UNG activity repairs activation-induced deaminase-generated U:G mismatches via error-prone or error-free repair, depending on the sequence context of the deaminated cytosine.
Key Points
miR-217 enhances the GC reaction by dampening genotoxic-induced Bcl-6 degradation in GC B cells. miR-217 is an oncogene and its overexpression provides a model of miRNA-induced mature B-cell lymphomagenesis.
The generation of an efficient immune response depends on highly refined mechanisms of antibody diversification. Two of these mechanisms, somatic hypermutation (SHM) and class switch recombination (CSR), are initiated by activation-induced cytidine deaminase (AID) upon antigen stimulation of mature B cells. AID deaminates cytosines on the DNA of Ig genes thereby generating a lesion that can be processed into a mutation (SHM) or a DNA double-strand break followed by a recombination reaction (CSR). A number of mechanisms are probably responsible for regulating AID function, such as transcriptional regulation, subcellular localization, post-transcriptional modifications and target specificity, but the issue remains of how unwanted DNA damage is fully prevented. Most lymphocyte neoplasias are originated from mature B cells and harbour hallmark chromosome translocations of lymphomagenic potential, such as the c-myc/IgH translocations found in Burkitt lymphomas. It has been recently shown that such translocations are initiated by AID and that ataxia-telangiectasia mutated, p53 and ARF provide surveillance mechanisms to prevent these aberrations. In addition, evidence is accumulating that AID expression can be induced in B cells independently of the germinal centre environment, such as in response to some viral infections, and occasionally in non-B cells, at least in certain inflammation-associated neoplasic situations. The most recent findings on AID expression and function and their relevance to the generation of oncogenic lesions will be discussed.
Long-range enhancers govern the temporal and spatial control of gene expres s ion; however, the mechanisms that regulate enhancer activity during normal and malignant development remain poorly understood. Here, we demonstrate a role for aberrant chromatin accessibility in the regulation of MYC expression in T-cell lymphoblastic leukemia (T-ALL). Central to this process, the NOTCH1-MYC enhancer (N-Me), a long-range T cell-specifi c MYC enhancer, shows dynamic changes in chromatin accessibility during T-cell specifi cation and maturation and an aberrant high degree of chromatin accessibility in mouse and human T-ALL cells. Mechanistically, we demonstrate that GATA3driven nucleosome eviction dynamically modulates N-Me enhancer activity and is strictly required for NOTCH1-induced T-ALL initiation and maintenance. These results directly implicate aberrant regulation of chromatin accessibility at oncogenic enhancers as a mechanism of leukemic transformation. SIGNIFICANCE: MYC is a major effector of NOTCH1 oncogenic programs in T-ALL. Here, we show a major role for GATA3-mediated enhancer nucleosome eviction as a driver of MYC expression and leukemic transformation. These results support the role of aberrant chromatin accessibility and consequent oncogenic MYC enhancer activation in NOTCH1-induced T-ALL.
Early T-cell acute lymphoblastic leukemia (ETP-ALL) is an aggressive hematologic malignancy associated with early relapse and poor prognosis that is genetically, immunophenotypically, and transcriptionally distinct from more mature T-cell acute lymphoblastic leukemia (T-ALL) tumors. Here, we leveraged global metabolomic and transcriptomic profiling of primary ETP- and T-ALL leukemia samples to identify specific metabolic circuitries differentially active in this high-risk leukemia group. ETP-ALLs showed increased biosynthesis of phospholipids and sphingolipids and were specifically sensitive to inhibition of 3-hydroxy-3-methylglutaryl-CoA reductase, the rate-limiting enzyme in the mevalonate pathway. Mechanistically, inhibition of cholesterol synthesis inhibited oncogenic AKT1 signaling and suppressed MYC expression via loss of chromatin accessibility at a leukemia stem cell–specific long-range MYC enhancer. In all, these results identify the mevalonate pathway as a druggable novel vulnerability in high-risk ETP-ALL cells and uncover an unanticipated critical role for cholesterol biosynthesis in signal transduction and epigenetic circuitries driving leukemia cell growth and survival.
Significance:
Overtly distinct cell metabolic pathways operate in ETP- and T-ALL pointing to specific metabolic vulnerabilities. Inhibition of mevalonate biosynthesis selectively blocks oncogenic AKT–MYC signaling in ETP-ALL and suppresses leukemia cell growth. Ultimately, these results will inform the development of novel tailored and more effective treatments for patients with high-risk ETP-ALL.
This article is highlighted in the In This Issue feature, p. 587
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.