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dc.contributor.author Csermely, Péter
dc.contributor.author Hodsagi J,
dc.contributor.author Korcsmáros, Tamás
dc.contributor.author Módos, Dezső
dc.contributor.author Perez-Lopez AR,
dc.contributor.author Szalay, Kristóf Zsolt
dc.contributor.author Veres, Dániel
dc.contributor.author Földvári-Nagy Lászlóné Lenti, Katalin
dc.date.accessioned 2015-07-01T11:44:22Z
dc.date.available 2015-07-01T11:44:22Z
dc.date.issued 2015
dc.identifier 84892406261
dc.identifier.citation pagination=42-51; journalVolume=30; journalTitle=SEMINARS IN CANCER BIOLOGY;
dc.identifier.uri http://repo.lib.semmelweis.hu//handle/123456789/1918
dc.identifier.uri doi:10.1016/j.semcancer.2013.12.004
dc.description.abstract Cancer is increasingly perceived as a systems-level, network phenomenon. The major trend of malignant transformation can be described as a two-phase process, where an initial increase of network plasticity is followed by a decrease of plasticity at late stages of tumor development. The fluctuating intensity of stress factors, like hypoxia, inflammation and the either cooperative or hostile interactions of tumor inter-cellular networks, all increase the adaptation potential of cancer cells. This may lead to the bypass of cellular senescence, and to the development of cancer stem cells. We propose that the central tenet of cancer stem cell definition lies exactly in the indefinability of cancer stem cells. Actual properties of cancer stem cells depend on the individual "stress-history" of the given tumor. Cancer stem cells are characterized by an extremely large evolvability (i.e. a capacity to generate heritable phenotypic variation), which corresponds well with the defining hallmarks of cancer stem cells: the possession of the capacity to self-renew and to repeatedly re-build the heterogeneous lineages of cancer cells that comprise a tumor in new environments. Cancer stem cells represent a cell population, which is adapted to adapt. We argue that the high evolvability of cancer stem cells is helped by their repeated transitions between plastic (proliferative, symmetrically dividing) and rigid (quiescent, asymmetrically dividing, often more invasive) phenotypes having plastic and rigid networks. Thus, cancer stem cells reverse and replay cancer development multiple times. We describe network models potentially explaining cancer stem cell-like behavior. Finally, we propose novel strategies including combination therapies and multi-target drugs to overcome the Nietzschean dilemma of cancer stem cell targeting: "what does not kill me makes me stronger".
dc.relation.ispartof urn:issn:1044-579X
dc.title Cancer stem cells display extremely large evolvability alternating plastic and rigid networks as a potential mechanism Network models, novel therapeutic target strategies, and the contributions of hypoxia, inflammation and cellular senescence
dc.type Journal Article
dc.date.updated 2015-07-01T11:43:25Z
dc.language.rfc3066 en
dc.identifier.mtmt 2500257
dc.identifier.wos 000348086900006
dc.identifier.pubmed 24412105
dc.contributor.department SE/AOK/I/Orvosi Vegytani, Molekuláris Biológiai és Patobiokémiai Intézet
dc.contributor.department SE/ETK2007/AEI/Morfológiai és Fiziológiai Tanszék
dc.contributor.institution Semmelweis Egyetem


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