Abstract
BackgroundMutations in one allele of the TP53 gene in early stages are frequently followed by the loss of the remaining wild-type p53 (wtp53) allele (p53LOH) during tumor progression. Despite the strong notion of p53LOH as a critical step in tumor progression, its oncogenic outcomes that facilitate the selective pressure for p53LOH occurrence were not elucidated.MethodsUsing MMTV;ErbB2 mouse model of breast cancer carrying heterozygous R172H p53 mutation, we identified a novel gain-of-function (GOF) activity of mutant p53 (mutp53): the exacerbated loss of wtp53 allele in response to γ-irradiation.ResultsAs consequences of p53LOH in mutp53 heterozygous cells, we observed profound stabilization of mutp53 protein, the loss of p21 expression, the abrogation of G2/M checkpoint, chromosomal instability, centrosome amplification, and transcriptional upregulation of mitotic kinase Nek2 (a member of Never in Mitosis (NIMA) Kinases family) involved in the regulation of centrosome function. To avoid the mitotic catastrophe in the absence of G2/M checkpoint, cells with centrosome amplification adapt Nek2-mediated centrosomes clustering as pro-survival mutp53 GOF mechanism enabling unrestricted proliferation and clonal expansion of cells with p53LOH. Thus, the clonal dominance of mutp53 cells with p53LOH may represent the mechanism of irradiation-induced p53LOH. We show that pharmacological and genetic ablation of Nek2 decreases centrosome clustering and viability of specifically mutp53 cells with p53LOH.ConclusionIn a heterogeneous tumor population, Nek2 inhibition may alter the selective pressure for p53LOH by contraction of the mutp53 population with p53LOH, thus, preventing the outgrowth of genetically unstable, more aggressive cells.
Highlights
P53 is a tumor suppressor that plays a crucial role in inducing cancer cell death and growth arrest to protect the genome from the accumulation of DNA errors in response to genotoxic stress [1]
We sought to elucidate the functional outcomes of p53LOH that may generate the selective pressure for the loss of wtp53 allele during tumor progression in mutant p53 heterozygous mammary tumors leading to the expansion of cells with p53LOH
We focused on studying of Nek2 for the following reasons: (i) Nek2 plays an indispensable role for the entry into mitosis and G2/M progression, as it is required for centrosome assembly/maintenance, spindle formation, and chromosome segregation [34,35,36,37]. (ii) Nek2 overexpression promotes centrosome amplification and aneuploidy by disrupting the mitotic checkpoint, leading to malignant transformation [38, 39]. (iii) Silencing Nek2 with siRNA inhibited proliferation, induced cell death, and dramatically increased the
Summary
P53 is a tumor suppressor that plays a crucial role in inducing cancer cell death and growth arrest to protect the genome from the accumulation of DNA errors in response to genotoxic stress [1]. Understanding the precise mechanism and biological outcomes of p53LOH has been hindered by the lack of relevant experimental in vitro models It becomes an important clinical question as the targeting of p53LOH occurrence may lead to novel therapeutic strategies that delay or hinder tumor progression. We sought to elucidate the functional outcomes of p53LOH that may generate the selective pressure for the loss of wtp allele during tumor progression in mutant p53 (mutp53) heterozygous mammary tumors leading to the expansion of cells with p53LOH. Mutations in one allele of the TP53 gene in early stages are frequently followed by the loss of the remaining wild-type p53 (wtp53) allele (p53LOH) during tumor progression. Despite the strong notion of p53LOH as a critical step in tumor progression, its oncogenic outcomes that facilitate the selective pressure for p53LOH occurrence were not elucidated
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