Project description:Li-Fraumeni syndrome (LFS) is a rare, clinically and genetically heterogeneous inherited cancer syndrome. Most cases are due to mutations in TP53. CHK2 is a minor predisposing locus; we recently mapped a third locus to 1q23. In both TP53 and non-TP53 LFS, there is evidence for risk heterogeneity within and between kindreds, suggesting additional risk modifiers. Using BAC- and SNP-based microarrays, we performed genomic profiling of primary soft tissue sarcomas, osteosarcomas and matching constitutive samples of 10 LFS patients (6 with and 4 without TP53 mutations), to identify genome-wide patterns of copy number changes and loss-of-heterozygosity (LOH). Our complementing global approaches revealed several interesting patterns for TP53 and non-TP53 LFS tumors, including positive (1q/7, 3p/15, 4q/9q, 8q/19p, 9p/10q, 13/14 and 15q/18q) and negative (2q/9q, 3q/14q and 4q/6q) associations between chromosomal regions. The region containing the oncogene TWIST1 (7p21.1) was the most common gain independent of TP53 status and tumor type, while LOH of 8q11.2 with the tumor suppressor ST18 was the only region exclusively associated with non-TP53 soft tissue sarcomas. We resequenced known mutations in BRAF, KRAS and NRAS and identified somatic NRAS mutations in 2 of 10 tumors. TP53 and non-TP53 LFS tumors shared multiple hits in genes of the p53 and overlapping pathways. Although common dogma in cancer genetics holds that multiple hits in the same pathway are redundant and thus unlikely, we show that different combinations of genetic alterations in both TP53 and non-TP53 LFS tumors appear to act together in the p53 network in LFS tumorigenesis Keywords: Comparative genomic hybridization Using the Spectral Genomics dye-swap BAC arrays we studied 10 Li Fraumeni syndrome tumor cases

Project description:Cancer-related alterations of the p53 Tetramerization Domain (TD) abrogate wild-type (WT) p53 function. They result in a protein that preferentially forms monomers or dimers. These are also normal p53 states under basal cellular conditions. However, their physiological relevance is not well understood. We have established in vivo models for monomeric and dimeric p53 which model Li-Fraumeni Syndrome patients with germline p53 TD alterations. p53 monomers are inactive forms of the protein. Unexpectedly, p53 dimers conferred some tumor suppression that is not mediated by canonical WT p53 activities. p53 dimers upregulate the PPAR pathway. These activities are associated with lower prevalence of thymic lymphomas and inhibition of CD8+ T-cell accumulation. Lymphomas derived from dimeric p53 mice show cooperating alterations in the PPAR pathway, further implicating a role for these activities in tumor suppression. Our data reveal novel functions for p53 dimers and support the exploration of PPAR agonists as therapies.

Project description:Cancer-related alterations of the p53 Tetramerization Domain (TD) abrogate wild-type (WT) p53 function. They result in a protein that preferentially forms monomers or dimers. These are also normal p53 states under basal cellular conditions. However, their physiological relevance is not well understood. We have established in vivo models for monomeric and dimeric p53 which model Li-Fraumeni Syndrome patients with germline p53 TD alterations. p53 monomers are inactive forms of the protein. Unexpectedly, p53 dimers conferred some tumor suppression that is not mediated by canonical WT p53 activities. p53 dimers upregulate the PPAR pathway. These activities are associated with lower prevalence of thymic lymphomas and inhibition of CD8+ T-cell accumulation. Lymphomas derived from dimeric p53 mice show cooperating alterations in the PPAR pathway, further implicating a role for these activities in tumor suppression. Our data reveal novel functions for p53 dimers and support the exploration of PPAR agonists as therapies.

Project description:Cancer-related alterations of the p53 Tetramerization Domain (TD) abrogate wild-type (WT) p53 function. They result in a protein that preferentially forms monomers or dimers. These are also normal p53 states under basal cellular conditions. However, their physiological relevance is not well understood. We have established in vivo models for monomeric and dimeric p53 which model Li-Fraumeni Syndrome patients with germline p53 TD alterations. p53 monomers are inactive forms of the protein. Unexpectedly, p53 dimers conferred some tumor suppression that is not mediated by canonical WT p53 activities. p53 dimers upregulate the PPAR pathway. These activities are associated with lower prevalence of thymic lymphomas and inhibition of CD8+ T-cell accumulation. Lymphomas derived from dimeric p53 mice show cooperating alterations in the PPAR pathway, further implicating a role for these activities in tumor suppression. Our data reveal novel functions for p53 dimers and support the exploration of PPAR agonists as therapies.

Project description:Cancer-related alterations of the p53 Tetramerization Domain (TD) abrogate wild-type (WT) p53 function. They result in a protein that preferentially forms monomers or dimers. These are also normal p53 states under basal cellular conditions. However, their physiological relevance is not well understood. We have established in vivo models for monomeric and dimeric p53 which model Li-Fraumeni Syndrome patients with germline p53 TD alterations. p53 monomers are inactive forms of the protein. Unexpectedly, p53 dimers conferred some tumor suppression that is not mediated by canonical WT p53 activities. p53 dimers upregulate the PPAR pathway. These activities are associated with lower prevalence of thymic lymphomas and inhibition of CD8+ T-cell accumulation. Lymphomas derived from dimeric p53 mice show cooperating alterations in the PPAR pathway, further implicating a role for these activities in tumor suppression. Our data reveal novel functions for p53 dimers and support the exploration of PPAR agonists as therapies.

Project description:Cancer-related alterations of the p53 Tetramerization Domain (TD) abrogate wild-type (WT) p53 function. They result in a protein that preferentially forms monomers or dimers. These are also normal p53 states under basal cellular conditions. However, their physiological relevance is not well understood. We have established in vivo models for monomeric and dimeric p53 which model Li-Fraumeni Syndrome patients with germline p53 TD alterations. p53 monomers are inactive forms of the protein. Unexpectedly, p53 dimers conferred some tumor suppression that is not mediated by canonical WT p53 activities. p53 dimers upregulate the PPAR pathway. These activities are associated with lower prevalence of thymic lymphomas and inhibition of CD8+ T-cell accumulation. Lymphomas derived from dimeric p53 mice show cooperating alterations in the PPAR pathway, further implicating a role for these activities in tumor suppression. Our data reveal novel functions for p53 dimers and support the exploration of PPAR agonists as therapies.

Project description:Specific changes in gene expression during cancer initiation should enable discovery of biomarkers for risk assessment, early detection and targets for chemoprevention. It has been previously demonstrated that altered mRNA and proteome signatures of morphologically normal cells bearing a single inherited “hit” in a tumor suppressor gene parallel many changes observed in the corresponding sporadic cancer. Here, we report on the global gene expression profile of morphologically normal, cultured primary breast epithelial and stromal cells from Li-Fraumeni syndrome (LFS) TP53 mutation carriers. Our analyses identified multiple changes in gene expression in both morphologically normal breast epithelial and stromal cells associated with TP53 haploinsufficiency, as well as interlocking pathways. Notably, a dysregulated p53 signaling pathway was readily detectable. Pharmacological intervention with the p53 rescue compounds CP-31398 and PRIMA-1 provided further evidence in support of the central role of p53 in affecting these changes in LFS cells and treatment for this cancer. Because loss of signaling mediated by TP53 is associated with the development and survival of many human tumors, identification of gene expression profiles in morphologically normal cells that carry “one-hit” p53 mutations may reveal novel biomarkers, enabling the discovery of potential targets for chemoprevention of sporadic tumors as well. compare gene expression from different cell types

Project description:Li-Fraumeni syndrome (LFS) is a hereditary cancer predisposition syndrome associated with a highly penetrant and diverse tumor spectrum characterized by germline mutations in the TP53 tumor suppressor gene. To better understand how TP53 mutations predispose individuals with LFS to cancer development, we characterized tp53 R217H and R242H zebrafish lines as the first zebrafish p53 hotspot mutants (human R248 and R273H). These mutants have lost several key wildtype p53 functions and recapitulate many LFS phenotypes. Specifically, we have shown that the R217H and R242H alleles result in partial-to-no activation of key p53 target genes, are resistant to apoptosis in a dominant negative manner and exhibit a defective G1 cell-cycle checkpoint in vivo. The loss of these wildtype p53 functions predisposed the fish to develop spontaneous tumors as early as 6 months of age. Tumor histology resembles human sarcomas, a predominant LFS tumor type. tp53 R242H mutants developed tumors earlier with a higher lifetime incidence than tp53 null or R217H mutants, suggesting it is a more aggressive mutation, while the R217H allele may be hypomorphic. Additionally, we observed mutation-specific differences both in the tumor type and sex bias across tp53 null, R217H, and R242H genotypes with associated diverse transcriptomic and DNA methylome profiles, impacting metabolism, cell signalling, and biological macromolecule synthesis and degradation. These tp53 zebrafish mutants demonstrate fidelity to their human counterparts and provide new insights into underlying tumorigenesis mechanisms and kinetics, which may inform more tailored tumor surveillance approaches and novel therapeutic targets in LFS.

Project description:Li-Fraumeni syndrome (LFS) is a hereditary cancer predisposition syndrome associated with a highly penetrant and diverse tumor spectrum characterized by germline mutations in the TP53 tumor suppressor gene. To better understand how TP53 mutations predispose individuals with LFS to cancer development, we characterized tp53 R217H and R242H zebrafish lines as the first zebrafish p53 hotspot mutants (human R248 and R273H). These mutants have lost several key wildtype p53 functions and recapitulate many LFS phenotypes. Specifically, we have shown that the R217H and R242H alleles result in partial-to-no activation of key p53 target genes, are resistant to apoptosis in a dominant negative manner and exhibit a defective G1 cell-cycle checkpoint in vivo. The loss of these wildtype p53 functions predisposed the fish to develop spontaneous tumors as early as 6 months of age. Tumor histology resembles human sarcomas, a predominant LFS tumor type. tp53 R242H mutants developed tumors earlier with a higher lifetime incidence than tp53 null or R217H mutants, suggesting it is a more aggressive mutation, while the R217H allele may be hypomorphic. Additionally, we observed mutation-specific differences both in the tumor type and sex bias across tp53 null, R217H, and R242H genotypes with associated diverse transcriptomic and DNA methylome profiles, impacting metabolism, cell signalling, and biological macromolecule synthesis and degradation. These tp53 zebrafish mutants demonstrate fidelity to their human counterparts and provide new insights into underlying tumorigenesis mechanisms and kinetics, which may inform more tailored tumor surveillance approaches and novel therapeutic targets in LFS.

Project description:Multiple family members with cancer or individuals with multiple primary cancers are indicative of potential genetic etiology1. Germline mutations in TP53 cause a rare high penetrance cancer syndrome, Li Fraumeni Syndrome (LFS)2. We identified a TP53 tetramerization domain (TD) missense mutation c.1000G>C;p.G334R, in a family with LFS-associated cancers. Twenty-one additional probands were identified, and available tumors showed biallelic somatic inactivation of TP53. The majority of families were of Ashkenazi Jewish descent, and the TP53 c.1000G>C allele was found on a commonly inherited haplotype. While classical p53 target gene activation was maintained in p.G334R mutant cell lines treated with Nutlin-3a, a subset of p53 target genes, including PCLO, PLTP, PLXNB3 and LCN15, showed defective transactivation. Structural analysis demonstrated thermal instability of the mutant TD, and the G334R mutant protein showed increased preponderance of mutant conformation protein. TP53 c.1000G>C;p.G334R is a rare AJ-predominant mutation associated with low penetrance Li-Fraumeni Syndrome