53BP1 Oligomerization is Independent of its Methylation by PRMT1

p53 binding protein 1 (53BP1) participates in the repair of DNA double stranded breaks (DSBs) where it is recruited to or near sites of DNA damage. Although little is known about the biochemical functions of 53BP1, the protein possesses several motifs that are likely important for its role as a DNA damage response element. This includes two BRCA1 C-terminal repeats, tandem Tudor domains, and a variety of phosphorylation sites. Here we show that a glycine-arginine rich (GAR) stretch of 53BP1 lying upstream of the Tudor motifs is methylated. We demonstrate that arginine residues within this region are important for asymmetric methylation by the PRMT1 methyltransferase. We further show that sequences upstream of the Tudor domains that do not include the GAR stretch are sufficient for 53BP1 oligomerization in vivo. Thus, although Tudor domains bind methylated proteins, 53BP1 homo-oligomerization occurs independently of Tudor function. Lastly, we find that deficiencies in 53BP1 generate a "hyper-rec" phenotype. Collectively, these data provide new insight into 53BP1, an important component in maintaining genomic stability.

Organ-specific susceptibility of p53 knockout mice to N-bis(2-hydroxypropyl)nitrosamine carcinogenesis

To elucidate which is the major determinant of susceptibility of p53 deficient mice, the carcinogen or the target organ, N-bis(2-hydroxypropyl)nitrosamine was administered to induce tumors in multi-organs. In a 15-week experiment, the incidences of both lung and hepatic vascular tumors were found to be significantly higher in p53 nullizygous (-/-) than in heterozygous (+/-) and wild-type (+/+) mice, indicating universal susceptibility of p53 (-/-) mice. In a 40-week experiment, p53 (+/-) mice showed increased susceptibility only with regard to vascular tumors, coinciding with significantly more frequent (60%) p53 gene mutations, in comparison with lung tumors with their low mutation rate (10.8%) (P<0.005). These results indicate that the target organ may be a more important factor than the carcinogen in determining susceptibility of p53 (+/-) mice.

Probing p53 biological functions through the use of genetically engineered mouse models

The p53 tumor suppressor gene is rendered dysfunctional in the majority of human cancers. To model the effects of p53 dysfunction in an experimentally manipulable organismal context, genetically engineered inbred mice have been the models of choice. Transgenic and knock-out technologies have been utilized to generate an array of different p53 germ line alterations. As expected, many (though not all) of the mutant p53 mouse models are susceptible to enhanced spontaneous and carcinogen-induced tumors of a variety of types. A number of different variables affect the incidence and spectrum of tumors in p53 mutant mice. These include strain background, the nature of the p53 mutation, the presence of wild-type p53 (in addition to mutant p53), exposure to physical and chemical mutagens, or introduction of other cancer-associated genes into the mutant p53 background. In addition to their role in furthering our understanding of the mechanisms of cancer initiation and progression, these models have led to unexpected insights into p53 function in embryogenesis and aging. With the development of ever more sophisticated methods for manipulating the mouse genome, new p53 models are on the horizon, which should deliver advances that will provide not only important mechanistic insights but also discoveries of great clinical relevance.

Reversal of the ATM/ATR-mediated DNA damage response by the oncogenic phosphatase PPM1D

The eukaryotic cell has evolved a sophisticated set of cell signaling pathways that respond to DNA damage and efficiently repair that damage, protecting the cell from deleterious mutations, genomic instability, and transformation into a cancerous state. The ATM and ATR serine/threonine kinases are key sensors and transducers of DNA damage signals through phosphorylation of an array of signaling molecules that mediate all aspects of the DNA damage response, including enforcement of cell cycle checkpoints and direct repair of damaged DNA. We have shown that a type 2C serine/threonine phosphatase, PPM1D (or Wip1), can reverse the phosphorylation status of ATM/ATR-phosphorylated proteins p53 and Chk1. This dephosphorylation of p53 and Chk1 by PPM1D may result in reduced functional activities and is accompanied by suppression of DNA damage-induced cell cycle checkpoints and some aspects of DNA repair. Because PPM1D is transcriptionally activated by p53 in response to DNA damage, PPM1D may serve as a critical component of a p53 negative feedback regulatory loop since it now appears that PPM1D can inhibit p53 activity by at least four different molecular mechanisms. This may explain why PPM1D is amplified and overexpressed in a subset of human breast cancers that invariably retain wild type p53 alleles. We hypothesize that PPM1D is a homeostatic regulator of the DNA damage response that returns the cell to a more normal unstressed state following repair of the damage.

p53: guardian AND suppressor of longevity?

The p53 tumor suppressor gene enhances longevity by inhibiting cancer development. However, Van Heemst et al. in this issue show that polymorphisms in the p53 gene may affect longevity in unexpected ways. A meta-analysis indicates that individuals homozygous for the p53 codon 72 Pro allele instead of the more prevalent Arg allele have a modest increase in cancer incidence. This difference in cancer suspectibility is consistent with molecular studies showing that the p53 Pro polymorphic variant is a less robust anti-proliferative molecule than its Arg counterpart. The most surprising result was obtained in a prospective study of individuals age 85 or older. Despite having a 2.5-fold increased cancer incidence, the p53 codon 72 Pro/Pro individuals exhibited a significant 41% enhanced survival compared to codon 72 Arg/Pro and Arg/Arg individuals. These paradoxical findings suggest that p53 may enhance survival through most of our life span, but may actively suppress longevity during old age. The mechanisms for such duplicity remain unclear, but insights from p53 mutant mouse models may help to sort out the mystery.

PPM1D dephosphorylates Chk1 and p53 and abrogates cell cycle checkpoints

The ATM (ataxia-telangiectasia mutated) and ATR (ataxia-telangiectasia and Rad3-related) kinases respond to DNA damage by phosphorylating cellular target proteins that activate DNA repair pathways and cell cycle checkpoints in order to maintain genomic integrity. Here we show that the oncogenic p53-induced serine/threonine phosphatase, PPM1D (or Wip1), dephosphorylates two ATM/ATR targets, Chk1 and p53. PPM1D binds Chk1 and dephosphorylates the ATR-targeted phospho-Ser 345, leading to decreased Chk1 kinase activity. PPM1D also dephosphorylates p53 at phospho-Ser 15. PPM1D dephosphorylations are correlated with reduced cellular intra-S and G2/M checkpoint activity in response to DNA damage induced by ultraviolet and ionizing radiation. Thus, a primary function of PPM1D may be to reverse the p53 and Chk1-induced DNA damage and cell cycle checkpoint responses and return the cell to a homeostatic state following completion of DNA repair. These homeostatic functions may be partially responsible for the oncogenic effects of PPM1D when it is amplified and overexpressed in human tumors.

Lack of elevated liver carcinogenicity of aminophenylnorharman in p53-deficient mice

The hepatocarcinogenic potential of 9-(4'-aminophenyl)-9H-pyrido[3,4-b]indole (aminophenylnorharman, APNH) was investigated using male and female p53 deficient mice. Incidence of oval cell hyperplasia was 2/14 (14.3%), 14/23 (60.9%), and 2/10 (20%) in p53 nullizygous (-/-), heterozygous (+/-), and wild type (+/+) mice, respectively, exposed to 30 ppm APNH for 15 weeks, while hepatocellular anisonucleosis was observed only in APNH-treated p53 (-/-) mice. At 40 weeks, hepatocellular carcinomas had developed in 16/46 (34.8%) and 10/27 (37.0%) of female p53 (+/-) and (+/+) mice in contrast to only 1/45 (2.2%) and 2/12 (16.7%) in their male counterparts, respectively, without any detectable p53 gene mutations. Dose-dependent APNH-DNA adduct formation and transcriptional induction of CYP 1A1, but not CYP 1A2, was revealed with 7-day APNH treatment using female C57BL/6J mice. These results suggested hepatocarcinogenicity of APNH in mice could be linked to the liver microenvironment including hormonal milieu but independent of p53 expression and p53 gene mutations.

The p53-induced oncogenic phosphatase PPM1D interacts with uracil DNA glycosylase and suppresses base excision repair

The wild-type p53-induced phosphatase PPM1D (or Wip1) is a serine/threonine phosphatase that is transcriptionally upregulated by p53 following ultraviolet and ionizing radiation. PPM1D is an oncogene in transformation assays and is amplified or overexpressed in several human tumor types. Here, we demonstrate that PPM1D interacts with the nuclear isoform of uracil DNA glycosylase, UNG2, and suppresses base excision repair (BER). Point mutations that inactivate PPM1D phosphatase activity abrogate BER suppression, indicating that dephosphorylation by PPM1D is important for BER inhibition. We have identified UNG2 phosphorylation sites at threonines 6 and 126 that exhibit enhanced phosphorylation following UV irradiation. The UV-induced phosphorylated forms of UNG2 are more active than nonphosphorylated forms in mediating uracil-associated DNA cleavage. PPM1D dephosphorylation of UNG2 at phosphothreonine 6 is associated with reduced UNG2 activity. Thus, PPM1D may inhibit BER by dephosphorylating UNG2 to facilitate its inactivation after completion of DNA repair.

Diet-gene interactions in p53-deficient mice: insulin-like growth factor-1 as a mechanistic target

Progress in cancer prevention research is being facilitated by the use of animal models displaying specific genetic susceptibilities for cancer, such as mice deficient in one (+/-) or both (-/-) alleles of the p53 tumor suppressor gene. Our lab, which focuses on nutrition (particularly energy balance/obesity) and molecular carcinogenesis, has shown in p53-/- mice that calorie restriction (CR) increases the latency of spontaneous tumor development (mostly lymphomas) approximately 75%, decreases serum insulin-like growth factor (IGF)-1 and leptin levels, and induces apoptosis in immature (lymphoma-susceptible) thymocytes. In heterozygous p53-deficient (p53+/-) mice, CR and a one day/wk fast each significantly delay spontaneous tumor development (a mix of lymphomas, sarcomas, and epithelial tumors) and decreases serum IGF-1 and leptin levels, even when begun late in life. We are presently comparing and combining CR and exercise (treadmill and running wheel) to further elucidate the relationships between energy balance, p53, and tumorigenesis in these models. Furthermore, we have capitalized on the susceptibility of p53+/- mice to chronic, low-dose aromatic amine-induced bladder carcinogenesis to develop a model for evaluating bladder cancer prevention approaches. Using this model, we have established that IGF-1 mediates many of the anti-cancer effects of CR. We are currently conducting oligonucleotide microarray studies to further characterize diet-gene interactions underlying the anti-cancer effects of CR and to determine which of the CR-responsive genes are IGF-1 dependent.

Insights into aging obtained from p53 mutant mouse models

Cancer suppression is an integral component of longevity in organisms with renewable tissues. A number of genes in the mammalian genome function in cancer prevention, and some of these have been directly implicated in longevity assurance. One such longevity assurance gene is the tumor suppressor p53, a transcription factor that is mutated or dysregulated in most human cancers. Early studies have linked p53 to the induction of cellular senescence, whereas recent reports implicate it as a potential regulator of organismal aging. We have shown by gene inactivation studies that loss of p53 function enhances tumor susceptibility and reduces longevity in the mouse. A recent serendipitously generated p53 mutant allele resulted in a hypermorphic version of p53 that displays increased cancer resistance, yet also mediates decreased longevity. The reduced longevity is accompanied by the accelerated onset of a variety of aging phenotypes. These include a 20% decrease in median life span, early osteoporosis, lordokyphosis, organ atrophy, delayed wound healing, and a reduced regenerative response after various stresses. Since the initial characterization of these mutant mice, we have attempted to elucidate the underlying molecular and cellular mechanisms that could be influencing the early aging phenotypes. Molecular studies of the p53 mutant allele product indicate that it induces an increase in p53 activity in both in vitro and in vivo contexts. The age-associated loss of organ cellularity and reduced tissue regenerative responses in the mutant mice are consistent with an accelerated loss of stem cell functional capacity. Our model is that enhanced growth inhibitory activity of p53 produces an earlier loss of the ability of stem cells to produce adequate numbers of progenitor and mature differentiated cells in each organ. Currently, we are performing stem cell functional assays from p53 mutant and wild-type mice to test this model. One challenge for the future will be to find ways to manipulate p53 function to provide increased cancer resistance, yet still enhance overall organismal longevity.

Loss of Heterozygosity Occurs via Mitotic Recombination in Trp53+/− Mice and Associates with Mammary Tumor Susceptibility of the BALB/c Strain

Loss of heterozygosity (LOH) occurs commonly in cancers causing disruption of tumor suppressor genes and promoting tumor progression. BALB/c-Trp53(+/-) mice are a model of Li-Fraumeni syndrome, exhibiting a high frequency of mammary tumors and other tumor types seen in patients. However, the frequency of mammary tumors and LOH differs among strains of Trp53(+/-) mice, with mammary tumors occurring only on a BALB/c genetic background and showing a high frequency of LOH, whereas Trp53(+/-) mice on a 129/Sv or (C57BL/6 x 129/Sv) mixed background have a very low frequency of mammary tumors and show LOH for Trp53 in only approximately 50% of tumors. We have performed studies on tumors from Trp53(+/-) mice of several genetic backgrounds to examine the mechanism of LOH in BALB/c-Trp53(+/-) mammary tumors. By Southern blotting, 96% (24 of 25) of BALB/c-Trp53(+/-) mammary tumors displayed LOH for Trp53. Karyotype analysis indicated that cells lacking one copy of chromosome 11 were present in all five mammary tumors analyzed but were not always the dominant population. Comparative genomic hybridization analysis of these five tumors indicated either loss or retention of the entire chromosome 11. Thus chromosome loss or deletions within chromosome 11 do not account for the LOH observed by Southern blotting. Simple sequence length polymorphism analysis of (C57BL/6 x BALB/c) F1-Trp53(+/-) mammary tumors showed that LOH occurred over multiple loci and that a combination of maternal and paternal alleles were retained, indicating that mitotic recombination is the most likely mechanism of LOH. Nonmammary tumors of BALB/c mice also showed a high frequency of LOH (22 of 26, 85%) indicating it was not a mammary tumor specific phenomenon but rather a feature of the BALB/c strain. In (C57BL/6 x BALB/c) F1-Trp53(+/-) mice LOH was observed in 93% (13 of 14) of tumors, indicating that the high frequency of LOH was a dominant genetic trait. Thus the high frequency of LOH for Trp53 in BALB/c-Trp53(+/-) mammary tumors occurs via mitotic recombination and is a dominant genetic trait that associates with the occurrence of mammary tumors in (C57BL/6 x BALB/c) F1-Trp53(+/-) mice. These results further implicate double-strand DNA break repair machinery as important contributors to mammary tumorigenesis.

Generation and characterization of p53 mutant mice

p53 is one of the most well-characterized members of the tumor suppressor gene family. The role of p53 in controlling cellular homeostasis has proven critical, with over half of all human tumors having either lost or mutated p53. The emergence of technology facilitating the ablation of a gene within an animal's genome allowed great advances in the study of p53. The p53 knockout mouse was one of the first of its kind and provided a powerful tool for the study of p53. Production of the p53 knock-out mouse demonstrated the protein's dispensability during embryogenesis, while highlighting its essential role in controlling tumor formation. A variety of p53 mutant models have emerged since the original p53 knock-out mouse, along with improved techniques for regulating gene targeting. This chapter describes the necessary steps and protocols involved in producing a mutant mouse as well as the characterization that follows.

Suppression of thymic lymphomas and increased nonthymic lymphomagenesis inTrp53-deficient mice lacking inducible nitric oxide synthase gene

Trp53-deficient mice spontaneously develop lymphomas, mainly of thymic origin, although the molecular mechanism remains largely unknown. As several interaction effects between p53 and iNOS have been reported, we hypothesized that iNOS activity in the thymus is causally linked to lymphomagenesis in Trp53-deficient mice. We therefore created mouse strains with different combinations of the Trp53 and iNOS genes. Western blot and histologic analyses showed that the iNOS protein was constitutively expressed in the thymus independently of Trp53 status and its expression was enhanced in Trp53+/- and Trp53-/- mice compared to Trp53+/+ mice. Homozygous disruption of iNOS decreased the incidence of thymic lymphomas by almost 40% (p=0.087) and 90% (p<0.05) in Trp53-/- and Trp53+/- mice, respectively, compared to the respective iNOS wild-type mice but significantly (p<0.05) increased the development of nonthymic lymphomas in Trp53-/- and Trp53+/- mice. Although iNOS gene disruption did not affect the phenotype of thymic lymphomas, absence of the iNOS gene shifted the spectrum of nonthymic lymphoma from the B-cell to the T-cell lineage. RT-PCR analysis revealed enhanced expression of IL-10, which could have a promoting effect on lymphomagenesis, even without any stimulation, in the spleen of aging mice with the gene combinations Trp53-/-iNOS-/- and Trp53+/-iNOS-/- but not Trp53-/-iNOS+/+ or Trp53+/-iNOS+/+. These results suggest that iNOS could increase the development of thymic lymphomas in Trp53-deficient mice. While iNOS may have protective effects against nonthymic lymphomagenesis, the regulation of cytokine production by iNOS may be involved in the underlying mechanism of antilymphomagenesis effects in the peripheral lymphoid organ.

Cooperativity of p19ARF, Mdm2, and p53 in murine tumorigenesis

The p19ARF gene product responds to oncogenic stresses by interfering with the inhibitory effects of Mdm2 on p53, thus enhancing p53 activity and its antiproliferative functions. The absence of p19ARF in the mouse leads to early tumor susceptibility, presumably in part due to decreased p53 activity. To examine the tumorigenic cooperativity of p19ARF, Mdm2, and p53 in vivo, p19ARF-deficient mice were crossed first to p53-deficient mice and then to Mdm2 transgenic mice. The progeny were monitored for tumors. Cooperativity between p19ARF and p53 deficiencies in accelerating tumor formation was observed for most genotypes except p53-/- p19ARF-/- mice. p53-/- p19ARF-/- mice had a tumor incidence similar to p53-/- mice. In this context, tumor suppression by ARF appears to be primarily p53 dependent. The majority of the p19ARF+/- tumors deleted the wildtype p19ARF allele, in agreement with the previous studies, suggesting that p19ARF is a classic 'two hit' tumor suppressor. In a p53+/- background, however, all p19ARF+/- tumors retained a wildtype ARF allele and most also retained wildtype p53. In the second cross between p19ARF-deficient and Mdm2 transgenic mice, cooperativity in tumor incidence between Mdm2 overexpression and ARF deficiency was observed, consistent with the role of p19ARF in negatively regulating Mdm2 activity. These experiments further demonstrate in vivo the inter-relationships of the p19ARF-Mdm2-p53 signaling axis in tumor suppression.

Transgenic tumor models for carcinogen identification: the heterozygous Trp53-deficient and RasH2 mouse lines

Genetically altered mouse models (GAMM) for human cancers have been critical to the investigation and characterization of oncogene and tumor suppressor gene expression and function and the associated cancer phenotype. Similarly, several of the mouse models with defined genetic alterations have shown promise for identification of potential human carcinogens and investigation of mechanisms of carcinogen-gene interactions and tumorigenesis. In particular, both the B6.129N5-Trp53 mouse, heterozygous for a p53 null allele, and the CB6F1-RasH2 mouse, hemizygous for the human H-ras transgene, have been extensively investigated. Using 26-week exposure protocols at or approaching the maximum tolerated dose, the summary results to date indicate the potential for GAMM to identify and, possibly, classify chemicals of potential risk to humans using short-term carcinogenicity experiments. This IWGT session focused on: (1) the development of recommendations for genetic/molecular characterization required in animals, tissues, and tumors before and after treatment for identification of presumptive human carcinogens based on the current state of knowledge, (2) identification of data gaps in our current state of knowledge, and (3) development of recommendations for research strategies for further development of our knowledge base of these particular models. By optimization of protocols and identification of significant outcomes and responses to chemical exposure in appropriate short-term mechanism-based genetically altered rodent models, strategies for prevention and intervention may be developed and employed to the benefit of public health.

Cyclin D1 repression of peroxisome proliferator-activated receptor gamma expression and transactivation

The cyclin D1 gene is overexpressed in human breast cancers and is required for oncogene-induced tumorigenesis. Peroxisome proliferator-activated receptor gamma (PPAR gamma) is a nuclear receptor selectively activated by ligands of the thiazolidinedione class. PPAR gamma induces hepatic steatosis, and liganded PPAR gamma promotes adipocyte differentiation. Herein, cyclin D1 inhibited ligand-induced PPAR gamma function, transactivation, expression, and promoter activity. PPAR gamma transactivation induced by the ligand BRL49653 was inhibited by cyclin D1 through a pRB- and cdk-independent mechanism, requiring a region predicted to form an helix-loop-helix (HLH) structure. The cyclin D1 HLH region was also required for repression of the PPAR gamma ligand-binding domain linked to a heterologous DNA binding domain. Adipocyte differentiation by PPAR gamma-specific ligands (BRL49653, troglitazone) was enhanced in cyclin D1(-/-) fibroblasts and reversed by retroviral expression of cyclin D1. Homozygous deletion of the cyclin D1 gene, enhanced expression by PPAR gamma ligands of PPAR gamma and PPAR gamma-responsive genes, and cyclin D1(-/-) mice exhibit hepatic steatosis. Finally, reduction of cyclin D1 abundance in vivo using ponasterone-inducible cyclin D1 antisense transgenic mice, increased expression of PPAR gamma in vivo. The inhibition of PPAR gamma function by cyclin D1 is a new mechanism of signal transduction cross talk between PPAR gamma ligands and mitogenic signals that induce cyclin D1.

Development of an HIV-based cDNA expression cloning system

Expression cloning of cDNAs is a powerful tool with which to identify genes based on their specific functional properties. Here we describe the development of a cDNA library transfer system based on the human immunodeficiency virus type-1 (HIV). This system represents an improvement over current oncoretroviral cDNA expression systems in terms of target cell range and the inclusion of a selectable marker. By use of a simple packaging system, we were able to produce high-titer vector stocks from HIV vector-based cDNA libraries and demonstrate highly efficient cDNA expression cloning in three model experiments. First, HOS TK(-) cells, which are null for thymidine kinase (TK) expression, were transduced with an HIV-based cDNA library derived from primary human foreskin fibroblasts (HFFs) and functionally selected for TK expression. In a second experiment, hypoxanthine guanine phosphoribosyltransferase-1-deficient (HPRT(-)) fibroblasts were transduced with a T cell (PM1) line-derived cDNA library and selected for HPRT expression. Both TK (frequency 1 in 5.0 x 10(4)) and HPRT (frequency 1 in 2.0 x 10(4)) cDNAs were readily isolated from these HIV-based cDNA libraries. As a third example, we demonstrated the ability of this vector system to allow functional cDNA library screens to be performed in primary, mitotically inactive cell types. Using senescent HFFs as a target cell population, we were able to isolate SV40 large T antigen cDNA-containing clones (frequency 1 in 2.5 x 10(4)) based on their ability to overcome the senescence-induced block to cell proliferation. Thus, this system can be used to clone relatively low-abundance cDNAs based upon their expression. Because of the ability of HIV-based vectors to transduce primary and nondividing cells efficiently, this vector system will further broaden the range of cell types in which expression cloning studies can be performed.

High susceptibility of nullizygous p53 knockout mice to colorectal tumor induction by 1,2-dimethylhydrazine

PURPOSE

The susceptibility of male p53 nullizygote (-/-), heterozygote (+/-), and wild-type (+/+) mice to 1,2-dimethylhydrazine (DMH) induction of colon carcinogenesis was investigated.

METHODS

In a preliminary short-term experiment, male mice of three genotypes were given s.c. of 20 mg/kg DMH once weekly for 5 weeks. In a medium-term experiment, mice were given weekly s.c. of DMH for 15 weeks. In a long-term experiment, male p53 (+/-) and (+/+) mice were given weekly injections of DMH for 15 weeks, and killed at week 30.

RESULTS

In the medium-term experiment, carcinomas were observed in 70% of p53 (-/-) mice, although there were no carcinomas in p53 (+/+) and (+/-) mice. In the long-term experiment, there was no significant difference in incidences of adenomas and carcinomas between p53 (+/+) and (+/-) mice. PCR-single strand conformation polymorphism analysis of exons 5-8 of p53 gene revealed four mutations in one focal atypia, one adenoma, and two carcinomas, out of 56 colonic proliferative lesions in the medium- and long-term experiments.

CONCLUSIONS

These results suggest that p53 might not be a direct target of DMH but complete loss of p53 might elevate susceptibility to DMH-induced colorectal carcinogenesis.

Activities of wildtype and mutant p53 in suppression of homologous recombination as measured by a retroviral vector system

DNA repair of double strand breaks, interstrand DNA cross-links, and other types of DNA damage utilizes the processes of homologous recombination and non-homologous end joining to repair the damage. Aberrant homologous recombination is likely to be responsible for a significant fraction of chromosomal deletions, duplications, and translocations that are observed in cancer cells. To facilitate measurement of homologous recombination frequencies in normal cells, mutant cells, and cancer cells, we have developed a high titer retroviral vector containing tandem repeats of mutant versions of a GFP-Zeocin resistance fusion gene and an intact neomycin resistance marker. Recombination between the tandem repeats regenerates a functional GFP-Zeo(R) marker that can be easily scored. This retroviral vector was used to assess homologous recombination frequencies in human cancer cells and rodent fibroblasts with differing dosages of wild type or mutant p53. Absence of wild type p53 stimulated spontaneous and ionizing radiation-induced homologous recombination, confirming previous studies. Moreover, p53(+/-) mouse fibroblasts show elevated levels of homologous recombination compared to their p53(+/+) counterparts following retroviral vector infection, indicating that p53 is haploinsufficient for suppression of homologous recombination. Transfection of vector-containing p53 null Saos-2 cells with various human cancer-associated p53 mutants revealed that these altered p53 proteins retain some recombination suppression function despite being totally inactive for transcriptional transactivation. The retroviral vector utilized in these studies may be useful in performing recombination assays on a wide array of cell types, including those not readily transfected by normal vectors.

Elevated susceptibility of the p53 knockout mouse esophagus to methyl-N-amylnitrosamine carcinogenesis

Mutations of the p53 tumor suppressor gene constitute one of the most frequent molecular changes in a wide variety of human cancers, including those in the esophagus. Mice deficient in p53 have recently attracted attention for their potential to identify chemical genotoxins. In this study we investigated the susceptibility of p53 nullizygous (-/-), heterozygous (+/-) and wild-type (+/+) mice to methyl-N-amylnitrosamine (MNAN), which specifically induces esophageal tumors in mice and rats. The p53 (+/-) and (+/+) mice were treated with 5 or 15 p.p.m. MNAN in their drinking water for 8 weeks then maintained without further treatment for an additional 7 or 17 weeks, being killed at experimental weeks 15 or 25. An additional group of p53 (-/-) mice were given 5 p.p.m. MNAN for 8 weeks and killed at week 15. At 15 weeks in the 5 p.p.m. groups, squamous cell carcinomas (SCCs) were observed in 10/12 (83.3%) p53 (-/-) and 1/15 (6.7%) p53 (+/-) mice, but in none of the p53 (+/+) mice. In the animals receiving 15 p.p.m., 2/14 (14.3%) p53 (+/-) and 1/11 (9.1%) p53 (+/+) mice developed SCCs. At 25 weeks, the incidence of SCCs was 7/16 (43.8%) and 8/14 (57.1%) in p53 (+/-) mice and 1/13 (7.7%) and 2/10 (20.0%) in p53 (+/+) mice at 5 and 15 p.p.m., respectively. Of the SCCs examined by PCR-single strand conformation polymorphism analysis, 61% (14/23) from p53 (+/-) and 50% (6/12) from p53 (+/+) mice demonstrated mutations in the p53 gene (exons 5-8). These results indicate the order of susceptibility to MNAN-induced esophageal tumorigenesis to be as follows: nullizygotes (-/-) > heterozygotes (+/-) > wild-type (+/+), and provide strong evidence of involvement of p53 mutations in the development of esophageal SCCs.

Does p53 affect organismal aging?

The p53 protein plays a critical role in the prevention of cancer. It responds to a variety of cellular stresses to induce either apoptosis, a transient cell cycle arrest, or a terminal cell cycle arrest called senescence. Senescence in cultured cells is associated with augmented p53 activity and abrogation of p53 activity may delay in vitro senescence. Increasing evidence suggests that p53 may also influence aspects of organismal aging. Several mutant mouse models that display alterations in longevity and aging-related phenotypes have defects in genes that alter p53 signaling. Recently, my laboratory has developed and characterized a p53 mutant mouse line that appears to have an enhanced p53 response. These p53 mutants exhibit increased cancer resistance, yet have a shortened longevity and display a number of early aging-associated phenotypes, suggesting a role for p53 in the aging process. The nature of the aging phenotypes observed in this p53 mutant line is consistent with a model in which aging is driven in part by a gradual depletion of stem cell functional capacity.

Visual genotyping of a coat color tagged p53 mutant mouse line

The p53 knockout mouse has been widely used as a model in cancer research and other applications. Because neither homozygous nor heterozygous mutant p53 mice exhibit an overt phenotype, each animal requires laborious molecular genotyping. Here we describe a new p53 mutant mouse that is tagged with a tyrosinase coat color minigene. On an albino background, heterozygous tyrosinase-tagged p53 mutant mice exhibit a light tan coat color, while homozygous mutants display a darker brown coat color. Thus, by 8-10 days of age, mice with two, one, or no mutant p53 alleles are immediately distinguishable by their coat color, eliminating the time, costs, and errors associated with molecular genotyping. Moreover, the homozygous mutant p53-tyrosinase mice display a tumor incidence and spectrum virtually identical to previous p53 null mouse lines. Thus, tagging targeted mutations with such coat color markers provides a generally applicable genotyping method for embryonic stem cell-derived mice.