Role of Non-Homologous End-Joining in Repair of Radiation-Induced DNA Double-Strand Breaks

Karlsson, Karin

January 2006

<p>Efficient and correct repair of DNA damage, especially DNA double-strand breaks (DSBs), is vital for the survival of individual cells and organisms. Defects in the DNA repair may lead to cell death or genomic instability and development of cancer. </p><p>The repair of DSBs in cell lines with different DSB rejoining capabilities was studied after exposure to ionising radiation. A new cell lysis protocol performed at 0ºC, which prevents the inclusion of non-true DSBs in the quantification of DSBs by pulsed-field gel electrophoresis (PFGE), was developed. Results showed that when the standard protocol at 50ºC was used, 30-40% of the initial yield of DSBs corresponds to artifactual DSBs. The lesions transformed to DSBs during incubation at 50ºC were repaired within 60-90 minutes <i>in vivo</i> and the repair was independent of DNA-PK, XRCC1 and PARP-1.</p><p>Non-homologous end-joining (NHEJ) is the major DSB repair pathway in mammalian cells. We show that DSBs are processed into long single-stranded DNA (ssDNA) ends after ≥1 h of repair in NHEJ deficient cells. The ssDNA was formed outside of the G₁ phase of the cell cycle and only in the absence of the NHEJ proteins DNA-PK and DNA Ligase IV/XRCC4. The generation of ssDNA had great influence on the quantification of DSBs by PFGE. The standard protocol caused hybridisation of the ssDNA ends, resulting in overestimation of the DSB repair capability in NHEJ deficient cells.</p><p>DSBs were also quantified by detection of phosphorylated H2AX (γ-H2AX) foci. A large number of γ-H2AX foci still remaining after 21 h of repair in an NHEJ deficient cell line confirmed the low repair capability determined by PFGE. Furthermore, in normal cells difficulty in repairing clustered breaks was observed as a large fraction of γ-H2AX foci remaining 24 h after irradiation with high-LET ions.</p>

Molecular biology

DNA damage

DNA repair

DSB

NHEJ

DNA-PK

ionising radiation

high-LET

heat-labile sites

PFGE

Molekylärbiologi

Role of Non-Homologous End-Joining in Repair of Radiation-Induced DNA Double-Strand Breaks

Karlsson, Karin

January 2006

Efficient and correct repair of DNA damage, especially DNA double-strand breaks (DSBs), is vital for the survival of individual cells and organisms. Defects in the DNA repair may lead to cell death or genomic instability and development of cancer. The repair of DSBs in cell lines with different DSB rejoining capabilities was studied after exposure to ionising radiation. A new cell lysis protocol performed at 0ºC, which prevents the inclusion of non-true DSBs in the quantification of DSBs by pulsed-field gel electrophoresis (PFGE), was developed. Results showed that when the standard protocol at 50ºC was used, 30-40% of the initial yield of DSBs corresponds to artifactual DSBs. The lesions transformed to DSBs during incubation at 50ºC were repaired within 60-90 minutes in vivo and the repair was independent of DNA-PK, XRCC1 and PARP-1. Non-homologous end-joining (NHEJ) is the major DSB repair pathway in mammalian cells. We show that DSBs are processed into long single-stranded DNA (ssDNA) ends after ≥1 h of repair in NHEJ deficient cells. The ssDNA was formed outside of the G1 phase of the cell cycle and only in the absence of the NHEJ proteins DNA-PK and DNA Ligase IV/XRCC4. The generation of ssDNA had great influence on the quantification of DSBs by PFGE. The standard protocol caused hybridisation of the ssDNA ends, resulting in overestimation of the DSB repair capability in NHEJ deficient cells. DSBs were also quantified by detection of phosphorylated H2AX (γ-H2AX) foci. A large number of γ-H2AX foci still remaining after 21 h of repair in an NHEJ deficient cell line confirmed the low repair capability determined by PFGE. Furthermore, in normal cells difficulty in repairing clustered breaks was observed as a large fraction of γ-H2AX foci remaining 24 h after irradiation with high-LET ions.

Molecular biology

DNA damage

DNA repair

DSB

NHEJ

DNA-PK

ionising radiation

high-LET

heat-labile sites

PFGE

Molekylärbiologi

Gene targeting at and distant from DNA breaks in yeast and human cells

Stuckey, Samantha Anne

02 April 2013

Here we developed multiple genetic systems through which genetic modifications driven by DNA breaks caused by the I-SceI nuclease can be assayed in the yeast Saccharomyces cerevisiae and in human cells. Using the delitto perfetto approach for site-directed mutagenesis in yeast, we generated isogenic strains in which we could directly compare the recombination potential of different I-SceI variants. By genetic engineering procedures, we generated constructs in human cells for testing the recombination activity of the same I-SceI variants. Both in yeast and human cells we performed gene correction experiments using oligonucleotides (oligos) following modification and/or optimization of existing gene targeting protocols and development of new ones. We demonstrated that an I-SceI nicking enzyme can stimulate recombination on the chromosome in S. cerevisiae at multiple genomic loci. We also demonstrated in yeast that an I-SceI-driven nick can activate recombination 10 kb distant from the initial site of the chromosomal lesion. Moreover we demonstrated that an I-SceI nick can stimulate recombination at the site of the nick at episomal and chromosomal loci in human cells. We showed that an I-SceI double-strand break (DSB) could trigger recombination up to 2 kb distant from the break at an episomal target locus in human cells, though the same was not observed for the nick. Overall, we demonstrated the capacity for I-SceI nick-induced recombination in yeast and human cells. Importantly, our findings reveal that the nick stimulates gene correction by oligos differently from a DSB lesion, as determined by genetic and molecular analyses in yeast and human cells. This research illustrates the promise of targeted gene correction following generation of a nick.

Single-strand break (SSB)

Targeted gene correction

Double-strand break (DSB)

Yeast

Gene targeting

Mutagenesis

Chromosomes

Genetic recombination

Genetic engineering

Physical Layer Approach for Securing RFID Systems

Kaleem, Muhammad Khizer

January 2013

Radio Frequency IDentification (RFID) is a contactless, automatic identification wireless technology primarily used for identifying and tracking of objects, goods and humans. RFID is not only limited to identification and tracking applications. This proliferating wireless technology has been deployed in numerous securities sensitive applications e.g. access control, e-passports, contactless payments, driver license, transport ticking and health cards. RFID inherits all the security and privacy problems that are related to wireless technology and in addition to those that are specific to RFID systems. The security and privacy protection schemes proposed in literature for wireless devices are mostly secured through symmetric/asymmetric keys encryption/decryption and hash functions. The security of all these cryptographic algorithms depends on computationally complex problems that are hard to compute using available resources. However, these algorithms require cryptographic operations on RFID tags which contradict the low cost demand of RFID tags. Due to limited number of logic gates in tags, i.e., 5K-10K, these methods are not practical. Much research effort has done in attempt to solve consumer's privacy and security problem. Solutions that prevent clandestine inventory are mostly application layer techniques. To solve this problem, a new RFID physical layer scheme has been proposed namely Direct Sequence Backscatter Encryption (DSB Enc). The proposed scheme uses level generator to produce different levels before transmitting the signal to the tag. The tag response to the signal sent by the reader using backscatter communications on the same signal which looks random to the eavesdropper. Therefore eavesdropper cannot extract the information from reader to tag and tag to reader communication using passive eavesdropping. As reader knows the different generated levels added to the carrier signal, it can remove the levels and retrieve the tag's messages. We proposed a lightweight, low-cost and practically secure physical layer security to the RFID system, for a supply chain processing application, without increasing the computational power and tag's cost. The proposed scheme was validated by simulations on GNU Radio and experimentation using SDR and a WISP tag. Our implementation and experimental results validate that DSB Enc is secure against passive eavesdropping, replay and relay attacks. It provides better results in the presence of AWGN channel.

DSB Enc

RFID

USRP

SDR

GNU Radio

Level generator

Physical layer encryption

Software Defined Radio

Intel WISP tag

GRC

Security

DNA double-strand break repair studied by atomic force microscopy

Zabolotnaya, Ekaterina

January 2018

DNA double-strand breaks (DSBs), where both strands of the DNA duplex are simultaneously fractured, are considered the most lethal type of DNA damage. The conserved Mre11-Rad50 DNA repair complex enables the catalytic activities of the Mre11 nuclease and the Rad50 ATPase to function together to coordinate the recognition and processing of DSBs prior to the recruitment of long-range end-resection machinery required to trigger the DSB repair by the homologous recombination (HR) pathway. Fast-scan atomic force microscopy (AFM) in fluid conditions was primarily used to explore the architectural arrangement, DNA binding and processing machinery of the Mre11-Rad50 complex from the thermophilic crenarchaeote Sulfolobus acidocaldarius. The structural analysis identified four distinct architectural arrangements and demonstrates the key role of the Rad50 zinc hooks in the oligomerisation of the complex. AFM imaging showed a dynamic and Velcro-like interplay between Mre11-Rad50 protein complexes and the DNA double-helix using the Rad50 coiled-coils in a novel mode of DNA binding. The complex appears to use the Rad50 zinc hook region to bind to and track along dsDNA for broken DNA-terminals. Furthermore, the present study shows that this archaeal complex can drive extensive ATP-dependent unwinding of DNA templates. It is the first time that such unwinding has been observed in a single molecule study. These observations reveal novel activities leading to the proposal of a new model for Mre11-Rad50 action during DSB repair. AFM was also used to visualise the structure and activity of the HerA-NurA protein complex, which has been predicted to combine the activity of the NurA nuclease and hexameric HerA-translocase to generate long single-stranded DNA overhangs essential for DSB repair by HR in archaea. The present data verify and clarify the presumed biological role of this complex. Overall, the present study provides new insights into the initial steps of DNA DSB repair by the HR pathway and, most importantly, the detection of the broken ends.

The World Trade Organization (WTO) Appellate Body crisis: A critical analysis

Dhlamini, Phumelele Tracy

05 August 2021

The World Trade Organization (WTO) dispute settlement system is facing unprecedented challenges, following the United States (US) decision to block the appointment of all Appellate Body members. The US has justified its blocking tactic, already implemented since 2017 by raising several procedural and substantive concerns with the Appellate Body's failure to follow WTO rules. On 10 December 2019, the Appellate Body was forced to suspend its activities after the second terms of two of the remaining three members expired. While the WTO dispute settlement system continues to function at the panel stage, the Appellate Body is currently unable to review appeals because it lacks the minimum number of three members required to establish a division. In addition, the collapse of the Appellate Body means that any party to a dispute can block the adoption of a panel report by filing a notice to appeal which is likely to remain in limbo for an indefinite period. Numerous studies have discussed the Appellate Body crisis and its implications for the WTO dispute settlement system. Few, however, have critically analysed the validity of the concerns that the US has raised about the Appellate Body's work over the past few years. Therefore, the purpose of this research is to discuss and critically analyse these concerns to determine whether the Appellate Body has indeed strayed from its limited mandate. In addition, the research will provide recommendations on how to save the appellate stage and ensure that appeals are resolved while WTO members attempt to find permanent solutions to this unprecedented crisis.

Appellate Body

Dispute Settlement Body (DSB)

Dispute settlement system

Dispute Settlement Understanding (DSU)

and the World Trade Organization (WTO)

Inflammation and Altered Signaling in Obstetric Pathologies

Tsai, Ya-Fang

12 August 2021

The purpose of this research project was to elucidate the molecular interactions and detail the signaling pathways in obstetric pathologies. This work first seeks to understand inflammation related complications relevant to obstetrics. Prior research in our lab identified the implications of the receptor of advanced glycation end products (RAGE) during inflammatory response in the placenta. Current work identified the presence of DNA double-strand breaks (DNA-DSBs) in inflammation associated pregnancy complications of preeclampsia (PE) and preterm labor (PTL) and demonstrated the positive role of RAGE in repairing the damage. The confluent relevance of disrupted mitochondrial function and inflammation has been recognized in the etiology of numerous chronic diseases. Our current studies aim to understand the connections between energy metabolism and inflammation in pathologies of pregnancy complications. Previous research conducted in our laboratory has demonstrated the mediation of the Gas6/Axl pathway on the mechanistic target of rapamycin (mTOR), an important metabolic molecule. We observed the negative regulation of Gas6 treatment on the mTOR pathway and its negative effects on trophoblast cell invasion. In the current study looking at the aspect of energy regulation, we identified the activation of placental mTOR in gestational diabetes mellitus (GDM) and its decrease during PE and intrauterine growth restriction (IUGR). We further evaluated the regulation of mTOR on its downstream effector pyruvate kinase M2 (PKM2). We found that inhibition of mTOR decreased PKM2 activation; while PKM2 activation positively regulated trophoblastic invasion and rescued negative effects observed in our second-hand smoke IUGR murine model. Our work has opened a new direction of placental research, especially in pregnancy complications stemming from genomic instability. We also clarified details of mTOR and PKM2 meditated metabolic signaling that are crucial for future investigation on the dynamic metabolic regulation during pregnancy.

RAGE

DNA-DSB

mTOR

PKM2

preeclampsia

preterm labor

intrauterine growth restriction

gestational diabetes mellitus

placenta

pregnancy trophoblast

Life Sciences

Účinky procesu kryoprezervace na jádro a povrch buňky. Funkce a fyzikálně-chemické vlastnosti kryoprotektantů. / Influence of freezing and thawing process on cryopreserved cells nuclei and surfaces. Functions and physico-chemical properties of cryoprotectants.

Golan, Martin

January 2018

1 Abstract: Cryopreservation of cells is a complex process with many useful applications in basic biological research, medicine and agriculture. In this work we deepened the current understanding of the cryopreservation process both at physical and biological level. Results include characteristics of selected cryoprotectants (primarily DMSO, trehalose, antifreeze protein ApAFP752) in liquid phase, during phase transition and in solid phase, as well as their impact on cryopreserved cells states. Specifically, the level of cell viability, state of cell membrane and condition of cell nucleus (nuclear membrane, chromatin condensation, DNA strand breaks) are monitored over several time points after thawing. It is shown that S-phase cells (NHDF and MCF7 lines) suffer massive collapse of replication forks during cryopreservation which makes them much less suitable for cryopreservation than cells in other phases of the cell cycle. Several methods (most importantly Atomic Force Microscopy, Confocal Fluorescence Microscopy and Flow Cytometry) were used to examine the post-thaw state of cryopreserved cells. The acquired insights into cryodamage of cells can lead to optimization of current cryopreservation protocols and to more thorough evaluation of efficacy of future novel cryoprotectants.

Evaluating the enforcement of World Trade Organisation dispute settlement decisions

Walters, Zeph

January 2019

Magister Legum - LLM / The World Trade Organisation (WTO) deals with regulation of trade in goods, services and intellectual property between participating countries by providing a framework for negotiating trade agreements.1 Furthermore, it has implemented a dispute resolution process aimed at enforcing participants' adherence to WTO agreements. Ideally, all WTO member states have ‘a level playing field’ in terms of access and equal rights under the dispute settlement mechanism. Disputes should be resolved in a fair and impartial manner. However, the WTO’s DSS has been criticised for being undemocratic, non-transparent and accountable to none. 2

Appellate body (AB)

Dispute settlement body (DSB)

Enforcement of WTO panel decision

Trade agreements

World Trade Organisation (WTO

Altering the level of lamin B1 leads to double-strand break repair defects and replicative stress / L'altération du niveau de la lamine B1 induit des défauts de réparation de cassures double-brin et un stress réplicatif

Moussa, Angela

12 January 2018

La surexpression de la lamine B1, un composant majeur de l'enveloppe nucléaire, a été rapportée dans diverses tumeurs. Cependant, les causes et les conséquences de cette augmentation sur la stabilité du génome n'ont pas été étudiées à ce jour. En effet, l'instabilité du génome est considérée comme une caractéristique majeure des cellules cancéreuses. Pour assurer le maintien de la stabilité du génome, les cellules ont développé de multiples et complexes mécanismes parmi lesquels les voies de réparation de l'ADN et la gestion du stress réplicatif sont essentielles. Au cours de ma thèse, l'impact de l'augmentation de niveau de lamine B1 sur la stabilité du génome, en particulier sur la réparation de cassure double-brin (CDB) et sur le contrôle du stress réplicatif a été étudié. En effet, nous montrons qu'une augmentation de la lamine B1 entraîne une accumulation de CDB et leur persistance en réponse à l'irradiation (foyers γH2AX), en plus d'une sensibilité accrue à l'irradiation (formation de colonies et cassures chromosomiques). Les cellules surexprimant la lamine B1 montrent également des défauts de recrutement de 53BP1 aux sites de dommages d’ADN, couplés à une diminution de l'efficacité de la réparation de CDB par NHEJ (Non-Homologous End-Joining). De plus, nous avons identifié une interaction directe entre la lamine B1 et 53BP1 régulant le recrutement de ce dernier aux CDB. Nos résultats supportent un modèle dans lequel l'augmentation de la lamine B1 conduit à la séquestration de 53BP1, modifiant ainsi son recrutement aux CDBs. En parallèle, nous montrons que les cellules surexprimant la lamine B1 présentent des signes accrus de stress réplicatif tels que l'accumulation de foyers spontanés de p-RPA, l'augmentation des figures radiales lors du traitement par mitomycine C, et une sensibilité accrue au traitement par camptothécine. Nous avons en outre cherché à identifier les causes de l'augmentation du stress réplicatif dans ces cellules, et les conséquences potentielles, en particulier sur l'induction de phénotypes inflammatoires. En fait, nous montrons que la surexpression de la lamine B1 conduit à une diminution de l'efficacité de la réparation de CDB par la recombinaison homologue, couplée à un défaut de formation de foyers BRCA1 après irradiation. De plus, nous avons obtenu des données préliminaires suggérant une induction de l'inflammation lors de la surexpression de la lamine B1. En résumé, ce travail de Thèse a permis d’identifier un nouveau mécanisme régulant le recrutement de 53BP1 aux CDB par son interaction avec la lamine B1, et souligne le rôle de l'augmentation de la lamine B1 dans la promotion de l'instabilité génomique au moins partiellement par des défauts de réparation de CDB et une augmentation de stress réplicatif. Après confirmation de l'induction de phénotypes inflammatoires, nous aurions identifié des rôles de l'augmentation de la lamine B1 dans la promotion de deux caractéristiques majeures du cancer - l'instabilité génomique et l'inflammation - favorisant ainsi le rôle de la lamine B1 dans le développement tumoral et proposant cette dernière comme une cible thérapeutique antitumorale potentielle. / The overexpression of lamin B1, a major component of nuclear envelope, has been reported in various tumors. However, the causes and consequences of this increase on the genome stability have not been studied to date. Indeed, genome instability is considered a major hallmark of cancer cells. To ensure the maintenance of genome stability, cells have developed multiple complex mechanisms among which pathways of DNA repair and replication stress management are essential. Therefore, during my thesis the impact of an increased lamin B1 level on genome stability, in particular on double-strand break (DSB) repair and on the control of replication stress was studied. Indeed, we show that increased lamin B1 leads to an accumulation of DSBs and their persistence in response to irradiation (γH2AX foci), in addition to an increased sensitivity to irradiation (colony formation and chromosomal breaks). Lamin B1 overexpressing cells also show defects in the recruitment of 53BP1 to damage sites, coupled to a decreased efficiency of DSB repair by Non-Homologous End-Joining. Moreover, we identified a direct interaction between lamin B1 and 53BP1 regulating the latter’s recruitment to DSBs. Our results support a model where increased lamin B1 leads to the sequestration of 53BP1, thereby altering its recruitment to DSBs. In parallel, we show that cells overexpressing lamin B1 display increased signs of replication stress such as accumulation of spontaneous p-RPA foci, increased radial chromosomes upon mitomycin C treatment, and enhanced sensitivity to treatment with camptothecin. We further aimed to identify the causes of the increased replication stress in these cells, in addition to the potential consequences, in particular on the induction of inflammatory phenotypes. In fact, we show that lamin B1 overexpression leads to a decreased efficiency of DSB repair by Homologous Recombination, coupled to a defect in irradiation-induced BRCA1 foci formation. In addition, we obtained preliminary data suggesting a possible induction of inflammation upon lamin B1 overexpression. Altogether, this work identifies a novel mechanism regulating the recruitment of 53BP1 to damage sites through its interaction with lamin B1, and highlights the role of increased lamin B1 in promoting genome instability at least partially through defective DSB repair and increased replication stress. Upon confirming the induction of inflammatory phenotypes, we would have identified roles of increased lamin B1 in promoting two major hallmarks of cancer – genomic instability and inflammation - thereby favorizing a role for lamin B1 in tumor development and proposing the latter as a potential anti-tumor therapeutic target.

Lamine B1

53BP1

Instabilité du génome

Réparation CDB

Stress Réplicatif

Inflammation

Lamin B1

53BP1

Genome Instability

DSB repair

Replicative Stress

Inflammation