Hoffmann, R. A wiki for the life sciences where authorship matters. Nature Genetics (2008)

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Klein, M.A. et al.

Reduced latency but no increased brain tumor penetrance in mice with astrocyte specific expression of a human p53 mutant.

p53-germline mutations located in the core DNA-binding domain have been associated with a more dominant tumor penetrance especially for breast cancer and brain tumors. We previously reported an unusual accumulation of CNS tumors associated with a unique p53 germline mutation, Y236delta (deletion of codon 236). To test whether this tissue-specific tumor predisposition reflects a gain-of-function activity of Y236delta, we generated transgenic mice expressing Y236delta in astrocytes using the regulatory elements of the glial fibrillary acidic protein ( GFAP) gene. After transplacental exposure to N-ethyl-N-nitrosourea (25 mg/kg BW) brain tumors developed in 18% (7/39) of GFAP-Y236delta transgenic p53-/- mice, while in p53+/- mice the incidence was 28% (11/40) (P>0.3). However, the mean tumor latency for GFAP-Y236delta/ p53+/- mice was significantly shorter than for p53+/- mice, with 19.9 weeks vs 31.6 weeks (P=0.039), respectively. Taken together, cell specific expression of Y236delta results in an acceleration of tumor progression but does not confer a higher tumor penetrance. Conceivably, the transdominant effect of Y236delta provided a growth advantage early in the progression of neoplastic cells, since the endogenous p53 wild-type allele was lost in all brain tumors independent of the genotype. This reflects well observations from human astrocytic neoplasms with p53 mutations.[1]

References

Reduced latency but no increased brain tumor penetrance in mice with astrocyte specific expression of a human p53 mutant. Klein, M.A., Rüedi, D., Nozaki, M., Dell, E.W., Diserens, A.C., Seelentag, W., Janzer, R.C., Aguzzi, A., Hegi, M.E. Oncogene (2000) [Pubmed]

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