Stochastic fate of<i>p53-</i>mutant epidermal progenitor cells is tilted toward proliferation by UV B during preneoplasia

Klein, Allon M.; Brash, Douglas E.; Jones, Philip H.; Simons, Benjamin D.

doi:10.1073/pnas.0909738107

Cited by 103 publications

(110 citation statements)

References 32 publications

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“…To detect these events, they must be present in a substantial fraction of the parenchymal cells. In proliferating tissues, such as in the cases of p53 mutations in UV-irradiated skin (32) and some of the CNVs seen in normal blood cells (14), it seems probable that the somatic mutation conferred a growth advantage to the affected cells. In organs that undergo little or no proliferation in the adult, one possibility is that the observed CNV may have given a growth or differentiation advantage to the affected precursor cells during development.…”

Section: Discussionmentioning

confidence: 99%

Extensive genetic variation in somatic human tissues

O’Huallachain

Karczewski

Weissman

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

139

118

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Genetic variation between individuals has been extensively investigated, but differences between tissues within individuals are far less understood. It is commonly assumed that all healthy cells that arise from the same zygote possess the same genomic content, with a few known exceptions in the immune system and germ line. However, a growing body of evidence shows that genomic variation exists between differentiated tissues. We investigated the scope of somatic genomic variation between tissues within humans. Analysis of copy number variation by high-resolution array-comparative genomic hybridization in diverse tissues from six unrelated subjects reveals a significant number of intraindividual genomic changes between tissues. Many (79%) of these events affect genes. Our results have important consequences for understanding normal genetic and phenotypic variation within individuals, and they have significant implications for both the etiology of genetic diseases such as cancer and for immortalized cell lines that might be used in research and therapeutics.somatic mosiacism | genomic rearrangement

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Section: Discussionmentioning

confidence: 99%

Extensive genetic variation in somatic human tissues

O’Huallachain

Karczewski

Weissman

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

139

118

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“…If all point mutations conferred the same proliferative advantage, the first incomplete moment would also acquire an exponential size dependence, μ 1 ðn, tÞ ≈ e −n=NðtÞ , with NðtÞ = e νt and ν defining the net proliferative expansion rate of mutant progenitors (36). However, because such a size dependence would require all point mutations (synonymous and nonsynonymous) to confer precisely the same proliferative advantage, its relevance to the current 2 NOTCH2 NOTCH2 SALL1 SALL1 APOB SCN1A ERBB4 ERBB4 SPHKAP SPHKAP ADAM29 FAT4 FAT1 NSD1 FAT1 BAI3 BAI3 NOTCH1 NOTCH1 NOTCH1 study is unlikely.…”

Section: Nonneutral Expansion Of Rare Mutant Clonesmentioning

confidence: 99%

Deep sequencing as a probe of normal stem cell fate and preneoplasia in human epidermis

Simons

2015

Proc. Natl. Acad. Sci. U.S.A.

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Using deep sequencing technology, methods based on the sporadic acquisition of somatic DNA mutations in human tissues have been used to trace the clonal evolution of progenitor cells in diseased states. However, the potential of these approaches to explore cell fate behavior of normal tissues and the initiation of preneoplasia remain underexploited. Focusing on the results of a recent deep sequencing study of eyelid epidermis, we show that the quantitative analysis of mutant clone size provides a general method to resolve the pattern of normal stem cell fate and to detect and characterize the mutational signature of rare field transformations in human tissues, with implications for the early detection of preneoplasia.stem cells | DNA sequencing | epidermis | cancer A dvances in genetic lineage tracing in transgenic animal models have provided important insights into the proliferative potential and fate behavior of stem and progenitor cell populations in normal tissues (1, 2). As well as providing constraints on the mechanisms that regulate stem cell self-renewal, these approaches have established a quantitative framework to address tumor initiation and progression (3-6). However, studies based on the clonal activation of oncogenes in animal models can fail to recapitulate the natural processes that lead to neoplasia in human tissues. In recent years, there has been increasing emphasis on the characterization of cancer genomes in human tissues and their potential to elucidate the pathways involved in tumor progression (7)(8)(9)(10)(11)(12)(13)(14). Although these studies have revealed a range of cancer genes (15), the heterogeneity and evolutionary diversity of the tumor environment make the separation of driver and passenger mutations challenging.Against the trend to focus on human tumor samples, a recent study has used ultradeep exome sequencing to determine the mutational profile of normal human eyelid epidermis (16). In the course of DNA replication, all dividing cells are subject to random SNPs. If the mutation rate is sufficiently low that their acquisition at a given locus in a cell subpopulation is typically associated with a single event, they confer a potentially unique hereditary label on cells, allowing the fate of their progeny to be traced over time. By resolving the mutant allele fraction in a biopsy using deep sequencing, the relative size of mutant clones can be inferred. A similar approach based on the spontaneous acquisition of mitochondrial DNA mutation has been used to address progenitor cell fate in human airways and intestinal epithelia (17,18). To assess the selective growth advantage of different mutations in normal epidermis, Martincorena et al. (16) compared the dN/dS ratio and average size of clones derived from mutations in genes associated with cancer drivers with those associated with synonymous mutations in nondriver genes. Their analysis showed a significant increase in the abundance and average size of clones that bear mutations in NOTCH1 and tumor protein p53 (TP53) compared wit...

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“…This may operate once cells become crowded, as restricting the contact area of keratinocytes with the underlying basement membrane promotes their differentiation. Similar cell crowding linked with slowing clonal expansion is seen in Tp53 mutant clones in human sun-exposed epidermis once they reach more than a thousand cells in size [39,41].…”

Section: However In Mouse Intestine Krasmentioning

confidence: 60%

“…Repeated exposure of mice to low doses of UV light, below the level which causes sunburn, generates similar immunoreactive Tp53 mutant clones in the epidermis [39,40]. A reanalysis of the size distribution of clones in both mouse and human epidermis argues that UV light drives the exponential expansion of TP53 mutant clones by increasing the probability of symmetric divisions generating two progenitor cells [41,42]. On cessation of UV exposure, the clones return to homeostatic behaviour, with some clones being lost through differentiation but the persisting clones expanding, so that the proportion of mutant cells is maintained.…”

Section: However In Mouse Intestine Krasmentioning

confidence: 99%

“…The mutant cell population will self-maintain over the winter, when there is little UV exposure, and expand during the summer, perhaps explaining the supralinear relationship between non-melanoma skin cancer incidence and life time UV dose, as cancer risk is dependent on the proportion of TP53 mutant cells [43,44]. Use of sunblock should thus be lifelong, as the proportionate reduction in risk will increase with age [41].…”

Section: However In Mouse Intestine Krasmentioning

confidence: 99%

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Mutation, clonal fitness and field change in epithelial carcinogenesis

2014

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Developments in lineage tracing in mouse models have revealed how stem cells maintain normal squamous and glandular epithelia. Here we review recent quantitative studies tracing the fate of individual mutant stem cells which have uncovered how common oncogenic mutations alter cell behaviour, creating clones with a growth advantage that may persist long term. In the intestine this occurs by a mutant clone colonizing an entire crypt, whilst in the squamous oesophagus blocking differentiation creates clones that expand to colonize large areas of epithelium, a phenomenon known as field change. We consider the implications of these findings for early cancer evolution and the cancer stem cell hypothesis, and the prospects of targeted cancer prevention by purging mutant clones from normal-appearing epithelia.

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Stochastic fate ofp53-mutant epidermal progenitor cells is tilted toward proliferation by UV B during preneoplasia

Cited by 103 publications

References 32 publications

Extensive genetic variation in somatic human tissues

Extensive genetic variation in somatic human tissues

Deep sequencing as a probe of normal stem cell fate and preneoplasia in human epidermis

Mutation, clonal fitness and field change in epithelial carcinogenesis

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