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dc.contributor.authorLopez-Contreras, Andres Joaquin
dc.contributor.authorFernandez-Capetillo, Oscar
dc.contributor.authorJoaquin, Andres
dc.contributor.authorFernandez-Capetillo, Oscar
dc.date.accessioned2025-03-08T01:14:11Z
dc.date.available2025-03-08T01:14:11Z
dc.date.issued2012
dc.date.submitted2019-10-04 14:39:07
dc.date.submitted2020-04-01T14:06:36Z
dc.date.submitted2016-08-01 23:55
dc.date.submitted2019-10-04 14:39:07
dc.date.submitted2020-04-01T14:06:36Z
dc.date.submitted2016-12-31 23:55:55
dc.date.submitted2019-10-04 14:39:07
dc.date.submitted2020-04-01T14:06:36Z
dc.identifier612634
dc.identifierOCN: 1030821210
dc.identifierhttp://library.oapen.org/handle/20.500.12657/32323
dc.identifier.urihttps://doab-dev.siscern.org/handle/20.500.12854/173952
dc.description.abstractDuring our lifetime, the genome is constantly being exposed to different types of damage caused either by exogenous sources (radiations and/or genotoxic compound) but also as byproducts of endogenous processes (reactive oxigen species during respiration, stalled forks during replication, eroded telomeres, etc). From a structural point of view, there are many types of DNA damage including single or double strand breaks, base modifications and losses or base-pair mismatches. The amount of lesions that we face is enormous with estimates suggesting that each of our 1013 cells has to deal with around 10.000 lesions per day [1]. While the majority of these events are properly resolved by specialized mechanisms, a deficient response to DNA damage, and particularly to DSB, harbors a serious threat to human health [2]. DSB can be formed [1] following an exposure to ionizing radiation (X- or γ-rays) or clastogenic drugs; [2] endogenously, during DNA replication, or [3], as a consequence of reactive oxygen species (ROS) generated during oxidative metabolism. In addition, programmed DSB are used as repair intermediates during V(D)J and Class-Switch recombination (CSR) in lymphocytes [3], or during meiotic recombination [4]. Because of this, immunodeficiency and/or sterility problems are frequently associated with DDR-related pathologies.
dc.languageEnglish
dc.rightsopen access
dc.subject.classificationthema EDItEUR::P Mathematics and Science::PD Science: general issues
dc.subject.otherdna damage
dc.subject.otherdna damage
dc.subject.otherApoptosis
dc.subject.otherAtaxia telangiectasia and Rad3 related
dc.subject.otherATM serine/threonine kinase
dc.subject.otherDNA repair
dc.subject.otherDNA-PKcs
dc.subject.otherPhosphorylation
dc.subject.otherProtein
dc.subject.otherUbiquitin
dc.titleChapter 8 Signalling DNA Damage
dc.typechapter
oapen.identifier.doi10.5772/50863
oapen.relation.isPublishedBy035ecc65-6737-43cf-a13a-6bdf67ce01f4
oapen.relation.isPartOfBookProtein Phosphorylation in Human Health
oapen.relation.isFundedByFP7 Ideas: European Research Council
oapen.relation.isFundedBy7292b17b-f01a-4016-94d3-d7fb5ef9fb79
oapen.collectionEuropean Research Council (ERC)
oapen.collectionEU collection
oapen.grant.number210520
oapen.grant.programFP7
dc.relationisFundedBy7292b17b-f01a-4016-94d3-d7fb5ef9fb79
dc.chapternumber1


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