TRAF Regulation of Caspase-2-Dependent Apoptosis in Response to DNA Damage

Robeson, Alexander

January 2016

<p>The DNA of a cell operates as its blueprint, providing coded information for the production of the RNA and proteins that allow the cell to function. Cells can face a myriad of insults to their genomic integrity during their lifetimes, from simple errors during growth and division to reactive oxygen species to chemotherapeutic reagents. To deal with these mutagenic insults and avoid passing them on to progeny, cells are equipped with multiple defenses. Checkpoints can sense problems and halt a cell’s progression through the cell cycle in order to allow repairs. More drastically, cells can also prevent passing on mutations to progeny by triggering apoptosis, or programmed cell death. This work will present two separate discoveries regarding the regulation of DNA damage-induced apoptosis and the regulation of the spindle checkpoint.</p><p> The protease caspase-2 has previously been shown to be an important regulator of DNA damage-induced apoptosis. In unstressed cells caspase-2 is present as an inactive monomer, but upon sensing a stress caspase-2 dimerizes and becomes catalytically active. The mechanisms that regulate this dimerization are poorly understood. The first research chapter details our development of a novel method to study dimerized caspase-2, which in turn identified TRAF2 as a direct activator of caspase-2. Specifically, we utilized the Bimolecular Fluorescence Complementation technique, wherein complementary halves of the Venus fluorophore are fused to caspase-2: when caspase-2 dimerizes, the non-fluorescent halves fold into a functional Venus fluorophore. We combined this technique with a Venus-specific immunoprecipitation that allowed the purification of caspase-2 dimers. Characterization of the caspase-2 dimer interactome by MS/MS identified several members of the TNF Receptor Associated Factor (TRAF) family, specifically TRAF1, 2, and 3. Knockdown studies revealed that TRAF2 plays a primary role in promoting caspase-2 dimerization and downstream apoptosis in response to DNA damage. Identification of a TRAF Interacting Motif (TIM) on caspase-2 indicates that TRAF2 directly acts on caspase-2 to induce its activation. TRAF2 is known to act as an E3 ubiquitin ligase as well as a scaffold for other E3 ubiquitin ligases. Indeed, we identified three lysine residues in the caspase-2 prodomain (K15, K152, and K153) important for its ubiquitination and complex formation. Together these results revealed a novel role for TRAF2 as a direct activator of caspase-2 apoptosis triggered by DNA damage.</p><p> During mitosis, when the cell prepares to divide, great care is taken to ensure that the chromosomes are properly segregated between the two daughter cells by the mitotic spindle. This is primarily accomplished through the spindle checkpoint, which becomes activated when the mitotic spindle is not properly attached to each chromosome’s kinetochore. When activated, the primary effector of the spindle checkpoint, the mitotic checkpoint complex (MCC), inhibits the anaphase-promoting complex (APC/C) by binding to the APC/C co-activator, CDC20. This prevents the APC/C from targeting critical pro-mitotic proteins, like cyclin B and securin, to promote mitotic exit. Although the function of the MCC is well understood, its regulation is not, especially in regard to protein phosphatases To investigate this, we activated the spindle checkpoint with microtubule inhibitors and then treated with a variety of phosphatase inhibitors, examining the effect on the MCC and APC/C. We found that two separate inhibitors, calyculin A and okadaic acid (1uM), were able to promote the dissociation of the MCC. This led to the activation of the APC/C, but the cells remained in mitosis as evidenced by high levels of Cdk1 activity and chromosome condensation. This is the first time that phosphatases have been shown to be essential to maintaining the MCC and an active spindle checkpoint.</p> / Dissertation

Molecular biology

Cellular biology

bimolecular fluorescence complementation

caspase-2

DNA damage

phosphatase

spindle checkpoint

Analysis of nucleotide synthesis and homologous recombination repair in Schizosaccharomyces pombe

Blaikley, Elizabeth Jane

January 2014

Nucleotide synthesis is a conserved and highly regulated response to DNA damage, required for the efficient repair of DNA double strand breaks (DSB) by homologous recombination (HR). This is essential to prevent loss of heterozygosity (LOH) and maintain genome stability. The aim of this study was to identify new genes important for HR through roles in damage-induced nucleotide synthesis. A screen was performed to identify S. pombe gene deletion strains whose DSB sensitivity was suppressed by deleting the ribonucleotide reductase (RNR) inhibitor spd1⁺ to promote nucleotide synthesis. The screen identified a number of genes including ddb1⁺, cdt2⁺, rad3⁺ and csn1⁺ which have known roles in nucleotide synthesis. Distinct roles were identified for the DNA damage checkpoint in suppressing LOH. rad3⁺, rad26⁺, rad17⁺ and the rad9⁺, rad1⁺ and hus1⁺ genes encoding the 9-1-1 complex were required for DNA damage-induced nucleotide synthesis through Cdt2 induction to promote Spd1 degradation. The HR repair defect of rad3⁺ and rad26⁺ deletion strains was partially suppressed by spd1⁺ deletion. However, the HR repair defect of rad17⁺, rad9⁺, rad1⁺ and hus1⁺ deletion strains was not suppressed. An additional role was confirmed for Rad17 and the 9-1-1 complex in preventing LOH by promoting DSB resection. A role was identified for the Gcn5 histone acetyl transferase (HAT) protein module, consisting of Gcn5, Ngg1, Ada2 and Sgf29, in suppressing DSB sensitivity by promoting nucleotide synthesis. This was independent of Cdt2 or RNR protein levels. The Gcn5 HAT module was also found to regulate DSB repair pathway choice consistent with previous observations. Deletion of gcn5⁺, ngg1⁺ or ada2⁺ decreased HR and increased non-homologous end joining. Surprisingly, deletion of spd1⁺ in a gcn5∆, ngg1∆ or ada2∆ background also promoted HR. This predicts a role for nucleotide pools in regulating DSB repair pathway choice. Eleven other candidates showed repeatable suppression of DSB sensitivity following spd1⁺ deletion. However many of these candidates did not show reduced nucleotide levels. This suggests deleting spd1⁺ may also suppress DSB sensitivity by a different mechanism.

572.8

Screening for inhibitors of and novel proteins within the homologous recombination DNA repair pathway

Kingham, Guy L.

January 2012

The homologous recombination (HR) pathway of DNA repair is essential for the faithful repair of double-stranded DNA breaks (DSBs) in all organisms and as such helps maintain genomic stability. Furthermore, HR is instrumental in the cellular response to exogenous DNA damaging agents such as those used in the clinic for chemo- and radiotherapy. HR in humans is a complex, incompletely understood process involving numerous stages and diverse biochemical activities. Advancing our knowledge of the HR pathway in humans aids the understanding of how chemo- and radiotherapies act and may be used to develop novel therapeutic strategies. Recent studies have identified inhibition of HR as one of the mechanisms via which a number of recently developed chemotherapeutics have their effect. Accordingly, the clinical potential of HR inhibitors is under investigation. My work has centred around the identification of both novel HR proteins and novel, small molecule HR inhibitors. To further these aims, I have successfully employed high-throughput RNAi and small molecule screening strategies. RNAi screens are commonly used to identify genes involved in a given cellular process via genetic loss of function, whilst small molecule, cell based screens are a powerful tool in the drug discovery process.

572.887

Mechanisms and Dynamics of Oxidative DNA Damage Repair in Nucleosomes

Cannan, Wendy J.

01 January 2016

DNA provides the blueprint for cell function and growth, as well as ensuring continuity from one cell generation to the next. In order to compact, protect, and regulate this vital information, DNA is packaged by histone proteins into nucleosomes, which are the fundamental subunits of chromatin. Reactive oxygen species, generated by both endogenous and exogenous agents, can react with DNA, altering base chemistry and generating DNA strand breaks. Left unrepaired, these oxidation products can result in mutations and/or cell death. The Base Excision Repair (BER) pathway exists to deal with damaged bases and single-stranded DNA breaks. However, the packaging of DNA into chromatin provides roadblocks to repair. Damaged DNA bases may be buried within nucleosomes, where they are inaccessible to repair enzymes and other DNA binding proteins. Previous in vitro studies by our lab have demonstrated that BER enzymes can function within this challenging environment, albeit in a reduced capacity. Exposure to ionizing radiation often results in multiple, clustered oxidative lesions. Near-simultaneous BER of two lesions located on opposing strands within a single helical turn of DNA of one another creates multiple DNA single-strand break intermediates. This, in turn, may create a potentially lethal double-strand break (DSB) that can no longer be repaired by BER. To determine if chromatin offers protection from this phenomenon, we incubated DNA glycosylases with nucleosomes containing clustered damages in an attempt to generate DSBs. We discovered that nucleosomes offer substantial protection from inadvertent DSB formation. Steric hindrance by the histone core in the nucleosome was a major factor in restricting DSB formation. As well, lesions positioned very close to one another were refractory to processing, with one lesion blocking or disrupting access to the second site. The nucleosome itself appears to remain intact during DSB formation, and in some cases, no DNA is released from the histones. Taken together, these results suggest that in vivo, DSBs generated by BER occur primarily in regions of the genome associated with elevated rates of nucleosome turnover or remodeling, and in the short linker DNA segments that lie between adjacent nucleosomes. DNA ligase IIIα (LigIIIα) catalyzes the final step in BER. In order to facilitate repair, DNA ligase must completely encircle the DNA helix. Thus, DNA ligase must at least transiently disrupt histone-DNA contacts. To determine how LigIIIα functions in nucleosomes, given this restraint, we incubated the enzyme with nick-containing nucleosomes. We found that a nick located further within the nucleosome was ligated at a lower rate than one located closer to the edge. This indicated that LigIIIα must wait for DNA to spontaneously, transiently unwrap from the histone octamer to expose the nick for recognition. Remarkably, the disruption that must occur for ligation is both limited and transient: the nucleosome remains resistant to enzymatic digest before and during ligation, and reforms completely once LigIIIα dissociates.

base exicison repair

chromatin

DNA damage

DNA enzymes

DNA repair

nucleosomes

Biochemistry

Genetics and Genomics

Molecular Biology

Depletion of the Chromatin Remodeler CHD4 Sensitizes AML Blasts to Genotoxic Agents and Reduces Tumor Formation

Sperlazza, Justin

01 January 2015

Chromodomain Helicase DNA-Binding Protein 4 (CHD4) is an ATPase that alters the phasing of nucleosomes on DNA and has recently been implicated in DNA double stranded break (DSB) repair. Here, we show that depletion of CHD4 in Acute Myeloid Leukemia (AML) blasts induces a global relaxation of chromatin that renders cells more susceptible to DSB formation, while concurrently impeding their repair. Furthermore, CHD4 depletion renders AML blasts more sensitive both in vitro and in vivo to genotoxic agents used in clinical therapy: daunorubicin (DNR) and cytarabine (ara-C). Sensitization to DNR and ara-C is mediated in part by activation of the ATM pathway, which is preliminarily activated by a Tip60-dependent mechanism in response to chromatin relaxation and further activated by genotoxic-agent induced DSBs. This sensitization preferentially affects AML cells, as CHD4 depletion in normal CD34+ hematopoetic progenitors does not increase their susceptibility to DNR or ara-C. Unexpectedly, we found that CHD4 is necessary for maintaining the tumor formatting behavior of AML cells, as CHD4 depletion severely restricted the ability of AML cells to form xenografts in mice and colonies in soft agar. Taken together, these results provide evidence for CHD4 as a novel therapeutic target whose inhibition has the potential to enhance the effectiveness of genotoxic agents used in AML therapy.

CHD4

Mi2-B

NuRD

Acute Myeloid Leukemia

DNA Damage Repair

Epigenetics

La voie de dégradation CRL4Cdt2 régule le recrutement des ADN polymérases translésionnelles eta et kappa en foyers nucléaires après endommagements aux UV-C en ciblant pour dégradation les protéines qui contiennent des PIP box spécialisées / The CRL4Cdt2 pathway regulates translesion DNA polymerase eta and kappa focus formation upon UV-C damage by targeting specialized PIP box-containing proteins for degradation

Tsanov, Nikolay

05 July 2012

La protéine PCNA est un facteur d'échafaudage polyvalent pour plus de cinquante protéines impliquées dans le métabolisme d'ADN, notamment dans la réplication et la réparation. Comment les échanges entre les partenaires de PCNA sont régulés est actuellement mal compris. Parmi ses partenaires, CDT1, p21 et PR-Set7/Set8 possèdent un motif d'interaction avec PCNA particulier, nommé « PIP degron », qui favorise leur protéolyse d'une manière dépendante de l'E3 ubiquitine ligase CRL4Cdt2. Après irradiation aux UV-C, le facteur d'initiation de la réplication CDT1 est rapidement détruit d'une manière dépendante de son PIP degron, mais le rôle de cette dégradation est inconnu. Dans cette étude, j'ai analysé la fonction du PIP degron de CDT1 et fourni des évidences expérimentales qui montrent que l'inhibition de la dégradation de Cdt1 par CRL4Cdt2 dans les cellules de mammifères compromet la relocalisation de l'ADN polymérase translesionnelle eta en foyers nucléaires induits par les irradiations UV-C. En élargissant cette étude à d'autres partenaires de PCNA, nous avons constaté que seuls les protéines qui contiennent un PIP degron, et pas un PIP box canonique comme celui de FEN1 et p15 (PAF), interfèrent avec la formation de foyers de pol eta. La mutagenèse du PIP degron de CDT1 a révélé qu'un résidu de thréonine conservé parmi les PIP degrons est essentiel pour l'inhibition de la formation des foyers de pol eta. Les résultats obtenus suggèrent que l'élimination de protéines contenant des PIP degrons par la voie CRL4Cdt2 régule le recrutement de pol eta au niveau des sites de dommages induits par les UV-C. / The sliding clamp PCNA is a versatile scaffold for more than fifty proteins involved in DNA metabolism such as replication and repair. How the switch between PCNA partners is regulated is currently not fully understood. Among its partners, Cdt1, p21 and PR-Set7/Set8 contain a specialized PCNA-binding motif named « PIP degron » that promotes their proteolysis in a fashion dependent on the E3 ubiquitin ligase CRL4Cdt2. Upon UV-irradiation, the replication initiation factor Cdt1 is rapidly destroyed in a PIP degron-dependent manner but the role of this degradation is unknown. Here we have analyzed the function of Cdt1 PIP degron and we provide evidence that interference with CRL4Cdt2-mediated destruction of Cdt1 in mammalian cells compromises PCNA-dependent relocalisation of the DNA translesion polymerase eta into UV-induced nuclear foci. By extending this analysis to other PCNA partners, we found that only PIP degrons, as compared to canonical PCNA-binding motifs of Fen1 and p15(PAF), interfere with pol eta focus formation. Mutagenesis of Cdt1 PIP degron revealed that a threonine residue conserved in PIP degrons is critical for inhibition of pol eta focus formation. Our results suggest that removal of high-affinity PIP degron-containing proteins from PCNA by CRL4Cdt2 pathway regulates pol eta recruitment to sites of UV-damage.

Endommagement de l'ADN

Synthese d'ADN translesionnelle

Degradation proteasomale

DNA damage

Translesion DNA synthesis

Proteasomal degradation

Detekce kovalentních komplexů DNA s proteiny jako metoda stanovení poškození DNA topoizomerázovými jedy. / DNA-protein covalent complexes detection as the means for the assessment of the DNA damage induced by topoisomerase poisons.

Karešová, Aneta

January 2016

Charles University in Prague Faculty of Pharmacy in Hradec Králové Department of Biochemical Sciences Candidate: Aneta Karešová Supervisor: PharmDr. Anna Jirkovská, PhD. Title of diploma thesis: DNA-protein covalent complexes detection as the means for the assessment of the DNA damage induced by topoisomerase poisons. Topoisomerase II is essential cellular enzyme, which modifies the secondary structure of DNA. By introducing a temporary double strand break to DNA it relieves a structural tension raised during transcription and translation. Absolutely indispensable is the role of topoisomerase II in the separation of sister chromatids synthesized in the S-phase of the cell cycle. The mechanism of DNA cleavage involves a covalent bond formed between active site tyrosine and 5' phosphate on both of the DNA strands and through the formed break the other strand or the other DNA molecule can pass. After that, the DNA strands are rejoined and topoisomerase II is detached. The indispensability of topoisomerase II mainly for proliferating cells makes it a great target for the antineoplastic drugs and the molecules belonging to the class of topoisomerase II inhibitors (etoposide, anthracyclines) are amongst the most useful anticancer drugs in the clinical practice. These clinically used "topoisomerase...

Deciphering the molecular mechanism by which Fml1 promotes and constrains homologous recombination

Nandi, Saikat

January 2011

Homologous Recombination (HR) can promote genome stability through its capacity to faithfully repair DNA gouble 2trand !;!reak2 (DSBs) and preventing the demise of stalled replication forks in part by catalysing template switching to enable DNA polymerase to bypass lesions. Despite these beneficial roles, inappropriate or untimely HR events can have deleterious consequences. HR can cause genome instability by recombining "inappropriate" homologous sequences, especially if the recombination intermediates are resolved to form crossovers. Over the past few years, study of the rare inherited chromosome instability disorder, Eanconi Anaemia (FA), has uncovered a novel DNA damage response pathway. Although the FA pathway is required primarily for interstrand DNA cross link repair, its precise role in DNA repair reactions is still unclear. FA.Qomplementation group M (FANCM) is the sole component within the FA core complex which possesses a DNA helicase/ATPase domain and an endonuclease domain (albeit non-functional), suggesting that FANCM could translocate along DNA and target the FA core complex to blocked replication forks. To further elucidate the role of FANCM in HR, I have purified Fm11, the FANCM orthologue in the fission yeast Schizosaccharomyces pombe and tested its activity on a range of synthetic replication and recombination intermediates in vitro. Fml1 binds both replication forks and Holliday Junctions (HJs) which are key intermediates of HR.

572.877

Role WSS1 proteasy v DNA reparačních procesech kvasinkové buňky. / Role of yeast WSS1 protease in DNA repair.

Adámek, Michael

January 2019

Sustaining the integrity of DNA throughout the lifetime is critical for every living organism. Therefore organisms evolved numerous ways to detect and repair different types of DNA damage caused by various endogenous and exogenous factors resulting in replication stress. Defects in these repair mechanisms can lead to severe human diseases such as neurological disorders, familial cancers or developmental syndromes. In presented master thesis, we investigated the function of a yeast protein named Wss1, a metalloprotease that participates in a recently discovered DNA repair pathway that proteolytically removes DNA-protein crosslinks. Wss1 shows strong negative interaction with another DNA repair protease, Ddi1, in which case was discovered, that double-deleted yeast strain lacking WSS1 and DDI1 is hypersensitive to hydroxyurea. Hydroxurea is a ribonucleotide reductase inhibitor that, in the end, arrests cells in the S-phase of cell-cycle. Based on previous studies, we performed rescue experiments with various deletions and single-site mutants of Wss1p to assess the involvement of particular yeast Wss1p domains in the replication stress response to hudroxyurea.

Efeito de lesões em DNA produzidas por luz Ultravioleta no processo de replicação do genoma de células de mamíferos / Effects of lesions in DNA produced by UV light in the genome replication of mammalian cells

Schumacher, Robert

15 December 1981

Estudou-se o comportamento frente a radiação UV de células humanas XP12RO, deficientes em reparo-excisão de dímeros de pirimidina. Cinéticas de incorporação de precursor radiativo de DNA em tempos crescentes apos a exposição a UV mostraram uma rápida inibição da taxa de síntese, até se alcançar um platô bem abaixo do valor obtido para células não irradiadas. Tanto o tempo para que este platô fosse alcançado quanto o valor basal de síntese obtido dependiam da dose de UV fornecida. Este tempo era compatível com o necessário para que a maquinaria de replicação percorresse a distância média interdímeros esperada para a dose de UV aplicada. Verificou-se também que o DNA recém-sintetizado após UV apresentava um peso molecular e uma taxa de elongação bem menores que nos controles não irradiados, sugerindo todos estes resultados que o dímero se constitue num bloqueio temporário para a replicação de DNA. Utilizando uma metodologia baseada no tratamento do DNA nativo com S1 endonuclease de Aspergillus oryzae, específica para DNA simples-fita, foi possível detectar a existência de lacunas de DNA replicado após UV, lacunas estas que desaparecem gradativamente com o passar do tempo pós-irradiação. DNA não irradiado manteve-se refratário à enzima, nas mesmas condições. A digestão enzimática acarretava o aparecimento de duas populações distintas de DNA, uma de alto peso molecular e outra de peso molecular bem menor, ambas se equivalendo em quantidade. Este fenômeno pôde ser observado em uma ampla faixa de doses de UV, tanto em células XP12RO como em outras linhagens celulares, e mesmo sob condições diversas de proliferação celular. Além disso, o desaparecimento das lacunas, no caso de células de roedor previamente irradiadas com UV, era retardado pela presença de cafeína, um conhecido inibidor de reparo pós-replicação (RPR) nestas linhagens. Foi efetuada uma análise da progressão da forquilha de replicação e da distribuição de lacunas do DNA replicado após UV, através de ensaios enzimáticos combinados com bandeamento de DNA em gradientes isopícnicos de CsCl. Os resultados assim obtidos levaram-nos a considerar um modelo de replicação a partir de molde lesado onde síntese descontínua (3\'-5\') propicia a formação de lacunas, enquanto que síntese contínua (5\'-3\') é retardada temporariamente pela presença da lesão, sem contudo acarretar a formação de descontinuidades físicas no DNA replicado. A mesma metodologia de digestão de DNA com S1 endonuclease permitiu verificar a ocorrência de uma nítida relação causal entre a frequência de lacunas e a frequência correspondente de dímeros, em crescentes doses de UV, sugerindo fortemente que dímeros estão opostos às lacunas no DNA recém sintetizado. Além disso, um tratamento estatístico da cinética de clivagens enzimáticas observada para as lacunas tornou possível calcular a extensão física destas, detectando-se a presença de duas populações distintas, onde 65% correspondem a 1250 nucleotídeos e 35% correspondem a 150 nucleotídeos. Finalmente, foi verificado que DNA recém-sintetizado longos tempos após UV apresenta um drástico declínio da frequência de lacunas, não obstante a frequência de dímeros permanecer essencialmente inalterada. Estes resultados favorecem a hipótese de ocorrer um processo induzido de RPR, o qual permitiria à maquinaria de replicação transpor eficientemente os dímeros presentes, apesar destes não terem propriedades codificadoras. / The synthesis of DNA in human XP12RO cells, deficient in excision repair of pyrimidine dimers was studied. The rate of incorporation of radioactive precursors into DNA was measured at different times after irradiation. The DNA synthesis decreases shortly after irradiation, reaching a lateau whose value and time to be attained was dependent on the UV dose. This time period was the one expected for the replication machinery to coyer the interdimer distance at the UV dose applied. It was also verified that the newly synthesized DNA after UV irradiation presented much smaller molecular weight and elongation rate, when compared with the non-irradiated controls. These results suggest that the dimer imposes a delay to DNA replication machinery. Using a methodology based on the treatment of native DNA with S1-endonuclease from Aspergillus orizae, specific for single-stranded DNA, it was possible to detect gaps in the DNA replicated after UV treatment. Thesee gaps disapeared gradually with time after irradiation. The nonirradiated DNA remained refractory to the enzyme, under the same experimental conditions. The enzymatic digestion originated approximately equal alounts of two distinct double-stranded DNA populations, one of high molecular weight and other of much smaller molecular weight. This fenomenon could be seen on a wide range of UV doses, in XP12RO cells as well as in other cells lines, and did not depend on the particular conditions of cell proliferation. Furthermore, the gap disappearence, in the case of rodent cells previously irradiated with UV, was delayed by the presence of caffeine, a known post-replication repair (PRR) inhibitor in these cell lines. An analysis of the progression of the replication fork and of the distribution of gaps in the DNA replicated after UV irradiation was carried out through enzymatic assays combined with DNA banding in isopicnic CsCl gradients. The results thus obtained led us to consider a model for replication on damaged template, whereby gaps are formed only in the strand replicating opposite the fork movement (3\'-5\'). The strand replicating in the same direction as the fork movement (5\'-3\') is temporarily delayed by the presence of the lesion, without originating gaps in the replicative DNA. The same methodology of DNA digestion with S1-endonuclease permitted us to verify the occurrence of a nitid relationship between the gap frequency and the corresponding dimer frequency, for different doses of UV, strongly suggesting that the dimers are opposite the gaps in the newly-synthesized DNA. Furthermore, an statistical analysis of the dependende of DNA cleavage by S1-endonuclease on the enzyme concentration rendered it possible to calculate the size of the gaps. Two distinct populations were detected, 65% corresponding to 1250 nucleotides and 35% corresponding to 150 nucleotides. Finally, it was verified that the nascent DNA synthesized long periods after UV are essentially free of gaps although the dimer frequency remained almost unaltered. These results favour the hypothesis of the occurrence of an induced process of PRR, which would permit the replication machinery to efficiently bypass the dimers, in spite of the fact that these lesions do not exhibit codifying properties.

Cell division

Danos do DNA

Divisão celular

DNA damage

DNA replication

Genomas

Genomes

Replicação do DNA