2021
Chromosomal instability accelerates the evolution of resistance to anti-cancer therapies
Lukow DA, Sausville EL, Suri P, Chunduri NK, Wieland A, Leu J, Smith JC, Girish V, Kumar AA, Kendall J, Wang Z, Storchova Z, Sheltzer JM. Chromosomal instability accelerates the evolution of resistance to anti-cancer therapies. Developmental Cell 2021, 56: 2427-2439.e4. PMID: 34352222, PMCID: PMC8933054, DOI: 10.1016/j.devcel.2021.07.009.Peer-Reviewed Original ResearchConceptsChromosomal instabilityAnti-cancer therapyCancer cell fitnessAcquisition of aneuploidyChromosome loss eventsSingle-cell sequencingEvolution of resistanceDifferent culture environmentsCellular fitnessPhenotypic plasticityCIN correlatesHuman tumorsCell fitnessHuman cellsStressful environmentsResistant populationsAcquisition of resistanceRecurrent aneuploidyCancer cellsPaclitaxel-resistant cellsCulture environmentAneuploidyPaclitaxel sensitivityFitnessCells
2019
Micronuclei-based model system reveals functional consequences of chromothripsis in human cells
Kneissig M, Keuper K, de Pagter MS, van Roosmalen MJ, Martin J, Otto H, Passerini V, Sparr A, Renkens I, Kropveld F, Vasudevan A, Sheltzer JM, Kloosterman WP, Storchova Z. Micronuclei-based model system reveals functional consequences of chromothripsis in human cells. ELife 2019, 8: e50292. PMID: 31778112, PMCID: PMC6910827, DOI: 10.7554/elife.50292.Peer-Reviewed Original ResearchConceptsMassive chromosomal rearrangementsChromosomal rearrangementsHuman cellsLamin B1Replication-dependent mechanismModel systemMicronucleus sizeProper assemblyAberrant replicationChromosome shatteringChromosome transferMembrane curvatureNuclear envelopeExtra chromosomeAberrant structuresDNA damageChromosomesGrowth advantageFunctional consequencesCancer cellsAbnormal numberTrisomic cellsCellsChromosomal aberrationsRearrangement