Non-homologous end joining

Summary

Non-homologous end joining (NHEJ) is a pathway that repairs double-strand breaks in DNA. NHEJ is referred to as "non-homologous" because the break ends are directly ligated without the need for a homologous template, in contrast to homology directed repair (HDR), which requires a homologous sequence to guide repair. NHEJ is active in both non-dividing and proliferating cells, while HDR is not readily accessible in non-dividing cells. The term "non-homologous end joining" was coined in 1996 by Moore and Haber. NHEJ is typically guided by short homologous DNA sequences called microhomologies. These microhomologies are often present in single-stranded overhangs on the ends of double-strand breaks. When the overhangs are perfectly compatible, NHEJ usually repairs the break accurately. Imprecise repair leading to loss of nucleotides can also occur, but is much more common when the overhangs are not compatible. Inappropriate NHEJ can lead to translocations an

Official source

https://en.wikipedia.org/wiki/Non-homologous_end_joining

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TRF2-Mediated Control of Telomere DNA Topology as a Mechanism for Chromosome-End Protection

Eric Aeby, Jing Ye

The shelterin proteins protect telomeres against activation of the DNA damage checkpoints and recombinational repair. We show here that a dimer of the shelterin subunit TRF2 wraps similar to 90 bp of DNA through several lysine and arginine residues localized around its homodimerization domain. The expression of a wrapping-deficient TRF2 mutant, named Top-less, alters telomeric DNA topology, decreases the number of terminal loops (t-loops), and triggers the ATM checkpoint, while still protecting telomeres against non-homologous end joining (NHEJ). In Top-less cells, the protection against NHEJ is alleviated if the expression of the TRF2-interacting protein RAP1 is reduced. We conclude that a distinctive topological state of telomeric DNA, controlled by the TRF2-dependent DNA wrapping and linked to t-loop formation, inhibits both ATM activation and NHEJ. The presence of RAP1 at telomeres appears as a backup mechanism to prevent NHEJ when topology-mediated telomere protection is impaired.

Cell Press2016

Telomeres are dynamic nucleo-protein structures capping the ends of all eukaryotic chromosomes. Together with telomerase, they counteract replication-dependent telomere attrition. Additionally, they disguise the linear ends of the chromosome from the DNA damage response (DDR) machinery. Otherwise, the chromosome end would be recognized as a DSB and would elicit a deleterious DDR signal. Both of these functions contribute greatly to the maintenance of genome stability. Telomeres are composed of repetitive DNA sequences, protein complex dubbed shelterin and telomeric repeat-containing RNAs. In addition to the core protein complex, other proteins are important for proper telomere structure and function. Our laboratory has a longstanding interest in the discovery of novel factors that have indispensable roles in telomere biology. For that purpose, previous lab members developed a Quantitative Telomeric Chromatin Isolation protocol (QTIP) and detected binding of new proteins to long telomeres, SMCHD1 and LRIF1. Their function at telomeres is not described but they are shown to function in higher-order chromatin organization and genome-wide DDR. Understanding their role in telomere biology is important because the list of players involved in DDR at telomeres is far from complete and we know very little about how chromatin structure affects DDR activation. Thus, this thesis provides insights into the DDR at telomeres by studying the functions of SMCHD1 and LRIF1 and describes the implementation of a novel microscopy-based method to study the role of these proteins and shelterins in early steps of the DDR. Firstly, we describe crucial roles for SMCHD1 and LRIF1 in DDR activation at telomeres lacking shelterin protein TRF2. Removal of TRF2 leads to activation of the ATM kinase and elicits a DDR giving rise to persistent chromosome fusions. We show that LRIF1 and SMCHD1 removal leads to attenuation of ATM activation and subsequent DDR defect as well as impairment in non-homologous end joining (NHEJ) at unprotected telomeres. Considering that these phenotypes are rescued by removal of TPP1 and activation of the ATR kinase we propose that these proteins mainly participate in DDR signaling operating at uncapped telomeres. They are among the rare ones described to act early in the DDR cascade upon TRF2 removal. Stimulated by the discovery that SMCHD1 and LRIF1 function in X-chromosome compaction, we sought to test if they would function in remodeling telomeric chromatin. To do that, we have implemented super-resolution microscopy method (STORM) to measure sizes and shapes of normal human telomeres and ones lacking SMCHD, LRIF1, and shelterin. We have shown, by examination of thousands of telomeres, that removal of shelterin proteins leads to decompaction of only a small subset of telomeres. This decompaction is not required for efficient DDR activation, as the DDR was also efficiently elicited from compacted TRF2-depleted telomeres. Thus, we propose that DDR is triggered by changes at the molecular level in protein recruitment upon telomere deprotec-tion. In addition, transient removal of SMCHD1 and LRIF1 did not affect the compaction state of telo-meres as they do in the X-chromosome. Overall, we have described two novel factors that are important for DDR at uncapped telomeres and excluded the need for decompaction as the initial step of DDR at uncapped telomeres and excluded the need for decompaction as the initial step of DDR activation.

EPFL2018

Difficulties to replicate telomeres - the ends of our chromosomes - can cause telomere shortening andgenome instability. These difficulties are due to the repetitive DNA sequence and distinct structures at telomeresthat challenge the semi-conservative DNA replication machinery. Among the proteins that help toovercome the obstacles to telomere replication are factors known to be mutated in genetic diseases (forinstance WRN, BLM, RTEL1, CTC1), but we suspect that there are still factors and pathways unknown.DNA replication defects at telomeres manifest as smeary or multiple telomeric fluorescence in situ hybridization(FISH) signals on metaphase chromosomes - commonly called telomere fragility. To identify proteinsthat protect human telomeres from fragility, we depleted 71 proteins (including 8 controls) from HeLa cellsusing siRNA pools and analysed their metaphase chromosomes for fragile telomeres. The majority of theseproteins had been identified by QTIP-iPOND - a proteomic analysis of chromatin near telomere replicationforks. Among the 71 proteins that were depleted in the siRNA screen, we identified 29 novel proteins thatprevent telomere fragility and are therefore crucial to maintain genome stability. The telomere fragilityscreen validated QTIP-iPOND as a technique to identify telomere replication proteins. The hits identified inour telomere fragility screen may for example have functions in regulating telomeric chromatin compositionand compaction, regulating transcription of the telomeric long non-coding RNA TERRA and its associationwith telomeric chromatin, dealing with replication stress and stalled replication forks, modulating DNAdamage signalling and repair, modulating sister chromatid cohesion, and preventing oxidative stress.One of the 29 novel proteins identified in the telomere fragility screen is chromobox 8 (CBX8) whose functionat telomeres was investigated in further detail in this study. CBX8 is a component of the canonical polycombrepressive complex 1 (PRC1), an epigenetic regulator of gene expression. However, CBX8 also hasfunctions that are independent of the PRC1 complex. We show that human CBX8 prevents telomere fragilitycaused by RNA-DNA hybrids which could stall replication forks and induce homologous recombination.CBX8 depletion or knockout did however not affect telomeric RNA-DNA hybrid levels. We hypothesize thatCBX8 may be involved in repair activities at stalled replication forks that arise when the replisome encounterspersistent RNA-DNA hybrids. Moreover, we found that CBX8 localizes to telomeric repeat-binding factor2 (TRF2)-deficient telomeres in a manner that is dependent on RNA-DNA hybrids and ATM signalling.We demonstrate that H3K27me3 (trimethylated histone 3 lysine 27) marks, which have previously beensuggested to help recruitment of CBX proteins to chromatin via the CBX chromodomain, are dispensable forCBX8 recruitment to TRF2-deficient telomeres. Furthermore, we found that CBX8 promotes non-homologousend joining (NHEJ)-mediated telomere fusions of dysfunctional telomeres. We therefore hypothesizethat CBX8 is involved in repair activities that influence the DNA repair pathway choice at TRF2-deficient telomeres.

EPFL2022

EPFL2018

EPFL2022