Inactivation of the p53 oncogene by internal deletion or retroviral integration in erythroleukemic cell lines induced by Friend leukemia virus

The p53 gene is rearranged in a high proportion of erythroleukemic cell lines derived from the spleens of mice infected with Friend leukemia virus. These rearrangements result in either the synthesis of a truncated protein or the inactivation of the p53 gene. Here we have molecularly characterized the rearrangements in two murine erythroleukemic cell lines induced by Friend leukemia virus, DP20-1 and CB3, that contain a rearranged p53 gene and fail to express p53 protein. The rearrangement in the DP20-1 cell line is due to the insertion of Friend spleen focus-forming provirus (SFFV) in the 3' end of the p53 gene in intron sequences between exons 9 and 10. Transfection of molecular clones of this SFFV provirus into NIH3T3 cells results in the generation of infectious virus as determined by its ability, in the presence of helper virus, to induce rapid splenomegaly and polycythemia when injected into adult DBA/2J mice. Insertion of SFFV in DP20-1 cells resulted in the expression of an aberrant 2.9 kb RNA species. Analysis of a molecular clone of the rearranged p53 gene in a second cell line, CB3, revealed that the p53 gene in this clone has sustained a large deletion within the p53 gene resulting in the loss of coding sequences between exons 4 and 8. The 5' end of the deletion originates within exon 4 and extends 3' to within the eighth intron. The significance of these findings with regard to the multi-stage nature of Friend virus induced erythroleukemia is discussed.     

Rearrangements of the Pim-1, c-myc, and p53 genes in Friend helper virus-induced mouse erythroleukemias

The Friend helper leukemia virus (F-MuLV) induces in mice leukemias of the erythroid, lymphoid, and myeloblastic lineages. Erythroleukemic cell DNAs were examined for genetic alterations at loci described as common proviral integration regions in MuLV-induced myeloid or lymphoid leukemias or in Friend complex-induced erythroleukemias. No alteration of the Fim-1, Fim-2, Fim-3, pvt-1, and Spi-1 loci were detected in 17 erythroleukemias, p53 gene rearrangement was observed in 6 (30%) erythroleukemias and was always associated with a loss of the germ line allele. Interestingly, genetic alterations were also detected at two loci, c-myc and Pim-1, previously described as common provirus integration regions in T lymphoid leukemias. Rearrangements of these two genes were often associated with p53 gene alteration within the same tumor.     

Genetic mapping of a third Li-Fraumeni syndrome predisposition locus to human chromosome 1q23

Li-Fraumeni syndrome (LFS) is a clinically and genetically heterogeneous inherited cancer syndrome. Most cases ( approximately 70%) identified and characterized to date are associated with dominantly inherited germ line mutations in the tumor suppressor gene TP53 (p53) in chromosome 17p13.1. In a subset of non-p53 patients with LFS, CHEK2 in chromosome 22q11 has been identified as another predisposing locus. Studying a series of non-p53 LFS kindred, we have shown that there is additional genetic heterogeneity in LFS kindred with inherited predisposition at loci other than p53 or CHEK2. Using a genome-wide scan for linkage with complementing parametric and nonparametric analysis methods, we identified linkage to a region of approximately 4 cM in chromosome 1q23, a genomic region not previously implicated in this disease. Identification ofa third predisposing gene and its underlying mutation(s) should provide insight into other genetic events that predispose to the genesis of the diverse tumor types associated with LFS and its variants.     

Genetic study of lymphoma induction by Friend murine leukemia virus in crosses involving AKR mice

The AKR mouse strain is uniquely susceptible to thymic lymphoma. Friend murine leukemia virus (F-MuLV) induced thymic lymphoma in this strain after a median latency of 3-4 months, whereas in several other mouse strains F-MuLV caused erythroblastosis. In the investigation of genetic determinants of the AKR predisposition to thymic lymphoma, series of congenic mouse strains and progeny of crosses involving AKR mice were inoculated with F-MuLV; these mice were followed for the development of lymphoma. The results suggested that AKR genes on chromosomes 7 and 15, other than inherited ecotropic virus, are involved in the predisposition to rapid onset of thymic lymphoma after inoculation with F-MuLV.     

Detection of both mutant and wild-type p53 protein in normal skin fibroblasts and demonstration of a shared 'second hit' on p53 in diverse tumors from a cancer-prone family with Li-Fraumeni syndrome.

Germline transmission of mutant p53 gene in cancer-prone families with Li-Fraumeni syndrome has revealed a new role for p53 in the genetic predisposition to cancer. The studies reported here focus on the analysis of the expression of normal and mutant p53 RNA and protein in germline configuration and demonstrate that normal skin fibroblasts derived from members of a family with Li-Fraumeni syndrome express mutant p53Gly----Asp(245) protein and RNA at levels similar to the wild-type p53. Thus, these fibroblasts represent a unique biological system in which endogenous promoters are utilized for the expression of both mutant and normal p53. We have further extended the earlier observations on the analysis of mutant p53 with a limited number of tumors derived from individuals with Li-Fraumeni syndrome. Tumors arising from two different germ layers in four individuals in a single family clearly exhibited the loss of the wild-type allele and the retention of the mutant allele observed in the normal skin fibroblasts derived from the same individuals. These observations further support the notion that germline p53 mutation plays a key role in the tumorigenesis of individuals with Li-Fraumeni syndrome.     

A Mouse Erythroleukemia Cell Line Possessing Friend Spleen Focus-forming Virus gp55 Transgene and Temperature-sensitive Mutant p53 Gene

Two different erythroleukemia cell lines have been established from the splenic lesions of transgenic mice possessing the Friend spleen focus-forming virus (F-SFFV) gp55 gene. One showed a neardiploid karyotype and a temperature-sensitive (ts) p53 mutation, and the other, a hyper-triploid karyotype with double p53 mutations found by single-strand conformation polymorphism (SSCP) analysis. The cell lines both retained No.11 chromosomes on which p53 genes are localized. Another p53 allele in the cell line with the ts-p53 mutation appeared intact in the SSCP analysis of the genomic exon 5. The cells with the ts-mutant p53 gene showed no apparent change with temperature shift in their growth or dimethylsulfoxide-induced differentiation, although the wild-type p⁵³ gene on the other allele was not expressing. This ts-p53^val-135 gene made p53-deficient fibroblasts anchorageindependent at 37°C but not at 32°C. This non-virus-producing, mouse erythroleukemia cell line will be useful for the study of mutated p53 function during the induction of erythrodifferentiation or apoptotic change.     

Loss of p53 in F-MuLV induced-erythroleukemias accelerates the acquisition of mutational events that confers immortality and growth factor independence.

Erythroleukemias induced by Friend Murine Leukemia Virus (F-MuLV) involve the insertional activation of the proto-oncogene Fli-1, and the inactivation of the p53 tumor suppressor gene. While the activation of Fli-1 is an early, primary transforming event, p53 mutations are correlated with the immortalization of erythroleukemic cells in culture. In this study we have further analysed the role of p53 loss in F-MuLV induced erythroleukemias by examining the progression of this disease in p53 deficient mice. We found that p53-/- mice succumb to the disease more rapidly than p53+/+ littermates. Additionally, of the 112 tumors generated, 19 gave rise to immortal cell lines, eight of which were derived from p53-/- mice, and ten of which were from p53+/- mice. The ability of these primary tumor cells to grow in culture was associated with the complete loss of wild-type p53 in these cell lines. However, cells from many of the tumors induced in p53-/- hosts did not survive in vitro. These results suggest that the loss of p53 does not directly immortalize tumor cells. Instead, we have evidence to suggest that the loss of p53 promotes the accumulation of mutations that are required for survival in culture and that are capable of accelerating tumor progression in vivo. Indeed, mutations causing expression of the growth factor gene erythropoietin (Epo), were detected in two of seven Epo-independent cell lines from p53 deficient primary erythroleukemias. Moreover, the mechanism of activation of the Epo gene in one of these two Epo-independent cell lines involved genomic rearrangement, that is a hallmark of genetic instability. We propose that, in F-MuLV induced-erythroleukemias, p53 loss may encourage the accumulation of further mutations, subsequently conferring a growth advantage and immortality to the transformed erythroblasts.     

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.     

Hepatocellular carcinoma in WHV/N-myc2 transgenic mice: oncogenic mutations of beta-catenin and synergistic effect of p53 null alleles

The intronless N-myc2 gene was originally identified as the major target of hepatitis virus insertion in woodchuck liver tumors. Here we report that transgenic mice carrying the N-myc2 gene controlled by woodchuck hepatitis virus (WHV) regulatory sequences are highly predisposed to liver cancer. In a WHV/N-myc2 transgenic line, hepatocellular carcinomas or adenomas arose in over 70% of mice, despite barely detectable expression of the methylated transgene in liver cells. Furthermore, a transgenic founder carrying unmethylated transgene sequences succumbed to a large liver tumor by the age of two months, demonstrating the high oncogenicity of the woodchuck N-myc2 retroposon. Stabilizing mutations or deletions of beta-catenin were found in 25% of liver tumors and correlated with reduced tumor latency (P<0.05), confirming the important role of beta-catenin activation in Myc-induced tumorigenesis. The ability of the tumor suppressor gene p53 to cooperate with N-myc2 in liver cell transformation was tested by introducing a p53-null allele into WHV/N-myc2 transgenic mice. The loss of one p53 allele in transgenic animals markedly accelerated the onset of liver cancer (P=0.0001), and most tumors of WHV/N-myc2 p53+/Delta mice harbored either a deletion of the wt p53 allele or a beta-catenin mutation. These findings provide direct evidence that activation of N-myc2 and reduction of p53 levels act synergistically during multistage carcinogenesis in vivo and suggest that different genetic pathways may underlie liver carcinogenesis initiated by a myc transgene. Oncogene (2000).     

Effects of genetic background on tumorigenesis in p53-deficient mice

Mice with disrupted germline p53 alleles have been engineered by us and others and have been shown to have enhanced susceptibility to spontaneous tumors of various types. We monitored a large number of p53-deficient mice(p53+/? and p53?/?) and their wild-type littermates(p53+/+) of two different genetic backgrounds(129/5v and mixed C57BL/6 × 129/5v) up to 2 yr of age.p53+/? and p53?/? 129/Sv mice show accelerated tumorigenesis rates compared with their p53-deficient counterparts of mixed C57BL/6 × 129/Sv genetic background. The tumor spectra of the two strains of mice are similar except that almost half of 129/Sv p53?/? males develop malignant teratomas, whereas these tumors are rarely observed in C57BL/6 × 129/Sv mice and never in 129/Sv p53+/? males. In the study reported here, we further characterized the lymphomas that arose in the p53-nullizygous mice and found that over three-quarters of the lymphomas were of thymic origin and contained primarily immature(CD4+/CD8+) T-cells, whereas the remainder originated in the spleen and peripheral lymph nodes and were of B-cell type. The high incidence of early-onset lymphomas in the nullizygous mice makes these animals a good lymphoma model, whereas the heterozygous mice may be a useful model for Li-Fraumeni syndrome, a human inherited cancer predisposition.© 1995 Wiley-Liss, Inc     

p53 mosaicism with an exon 8 germline mutation in the founder of a cancer-prone pedigree.

Changes in the tumor-suppressor gene p53 are frequently acquired during the course of malignant development of human tumors. Recently, constitutional heterozygous mutations in p53 exon 7 have been identified as the primary cause of cancer predisposition in cases of the familial Li-Fraumeni cancer syndrome. These findings underline the need for extensive mutation screening in families with high cancer incidence. This report describes the detection and follow-up by two-dimensional single-strand conformation polymorphism analysis (2DSSCP) of a new germline mutation of p53 exon 8 in a case of suspected Li-Fraumeni syndrome. Although a high cancer incidence had been reported in the family history of the father of siblings suffering from brain tumor and rhabdomyosarcoma, a constitutional heterozygous p53 mutation was identified only in the affected children. Retrospective analysis of archival tissue of a half-sister who died several years ago from a tumor of previously uncertain diagnosis revealed the same mutation. The mutation had therefore occurred in the germ cells of the mother, who thus appears to be a mosaic. The cancer predisposition of the paternal ancestors must have been due to other factors.     

Role of genetic factors in breast cancer susceptibility.

Hereditary breast cancer is common and accounts for approximately 10-14% of all breast cancers. Knowledge of a family history of breast cancer may significantly influence diagnosis and therapy. Genetic heterogeneity has been demonstrated in familial breast cancer. Recently inherited mutations in the tumor suppressor gene p53, have been shown to be the underlying defect in the Li-Fraumeni syndrome. We have shown that defects in this gene also play a role in the predisposition to other familial breast cancers. The gene responsible for early onset familial breast and ovary cancer has recently been mapped to chromosome 17q21. For most of the sporadic breast cancers a multifactorial model, including variable genetic and environmental factors, has been considered. Two genetic risk factors which may predispose for a considerable portion of breast cancers are the gene causing ataxia telangiectasia (AT) and the gene that gives rise to proliferative breast disease (PBD). Identification of distinct genes enhancing the risk of breast cancer will give us the opportunity to identify high risk individuals. Such individuals may benefit from periodic examination affording the possibility of early diagnosis and treatment.     

Genetics and cancer.

In the past year we have witnessed significant progress in understanding the molecular basis of cancerogenesis and in identifying the genetic determinants of susceptibility to cancer. In particular, the finding that the same tumor suppressor genes play a pathogenic role in both the inherited and the sporadic forms of some childhood tumors has suggested that this gene class may also be involved in adult tumors derived from inherited familial cancer syndromes. The identification of the gene defect underlying the Li-Fraumeni syndrome, a germline mutation of the tumor suppressor gene p53, has fully confirmed that suggestion. Three other genes associated with the inherited cancer syndromes neurofibromatosis type I (NF-1) and familial adenomatous polyposis have been cloned and partially characterized. In addition to these genes, which have a relatively high penetrance and contribute directly to tumorigenesis, other genes that lead to cancer as a secondary effect seem to act in determining an individual's overall cancer risk. The latter genes are most likely related to defective processes of DNA repair or to regulation of carcinogen metabolism. In this context the analysis of models of murine strains with different genetic susceptibility to cancer of various organs may be a useful tool for unveiling the genetic basis for cancer susceptibility in individuals.     

Germ-line deletion of p53 reveals a multistage tumor progression in spi-1/PU.1 transgenic proerythroblasts

Activation of the spi-1/PU.1 proto-oncogene and loss of p53 function are genetic alterations associated with the emergence of Friend malignant erythroleukemic cells. To address the role of p53 during erythroleukemogenesis, spi-1 transgenic mice (spi-1-Tg) which develop erythroleukemia were bred with p53-deficient mice. Three classes of spi-1 transgenic mice differing in their p53 functional status (p53(+/+), p53(+/-) and p53(-/-)) were generated. These mice developed a unique pattern of erythroleukemia. In wild-type p53 spi-1-Tg mice, none of the primary erythroleukemic spleen cells displayed autonomous growth in vitro and in vivo. In contrast, in p53(+/-) spi-1-Tg mice, erythroleukemic cells gave rise to growth factor-independent cell lines and generated tumors in vivo. Malignancy was associated with loss of the wild-type p53 allele. The p53(-/-) spi-1-Tg mice developed erythroleukemia with a total incidence and a reduced latency compared to the two other genotypes. Unexpectedly, 50% of p53(-/-) spi-1-Tg erythroleukemic spleens generated cell lines that were strictly dependent upon erythropoietin (Epo) for proliferation, whereas the remainder proliferated independently of cytokines. Moreover, only 70% of these spleen cells were tumorigenic. These findings indicate that p53 germ-line deletion did not confer malignancy to spi-1-transgenic proerythroblasts. Moreover Epo independence and tumorigenicity appear as separable phenotypic characteristics revealing that the spi-1-Tg proerythroblasts progress towards malignancy through multiple oncogenic events.     

Effect of cyclophosphamide on Friend virus leukemogenesis in virus-sensitive and virus-resistant mice

The influence of cyclophosphamide (CY) on Friend virus leukemogenesis was studied in SJL/J, C57BL/10J, and C57BL/10J X SJL/J F1 (hereafter called B10SJF1) mice. All three differ in their susceptibility to the viral oncogenic effect. Immunosuppressive doses of CY, which by themselves produced no cancer, were followed 2 days later by injection of Friend leukemia virus. The virus doses were the same as used previously. Although in other experiments preinjection of various chemical carcinogens augmented leukemogenesis by Friend leukemia virus in SJL/J mice, in the present study, pretreatment by CY had no such effect. In contrast, CY increased Friend erythroleukemia incidence from 15 to 100% in B10SJF1 mice and from 0 to 85% in C57BL/10J mice. The disease in C57BL/10J mice had a 190-day incubation period, which is approximately 5 times that in the SJL/J and B10SJF1 mice. During this latent period, the C57BL/10J mice harbored infectious Friend leukemia virus in their plasma.     

Ultraviolet B radiation-induced skin cancer in mice defective in the Xpc, Trp53, and Apex (HAP1) genes: genotype-specific effects on cancer predisposition and pathology of tumors

Mutations in nucleotide excision repair (NER) genes in humans result in the UV-induced skin cancer-prone disease xeroderma pigmentosum (XP). Mouse models that mimic XP have provided an informative experimental system with which to study DNA repair, as well as the molecular pathology of UV radiation-induced skin cancer. We reported previously that mice defective in the Xpc gene (Xpc-/-) are highly predisposed to UVB radiation-induced skin cancer and that the appearance of skin cancer is more rapid in Xpc Trp53 double mutants. Extended studies now demonstrate an increased predisposition to UVB radiation-induced skin cancers in Xpc heterozygous mice compared with normal mice. We also show that Xpc Trp53 double heterozygous mutants are more predisposed to skin cancer than Trp53 single heterozygous mice. No mutations were detected in the cDNA of the remaining Xpc allele, suggesting that haploinsufficiency of the Xpc gene may be operating and is a risk factor for UVB radiation-induced skin cancer in mice. Skin tumors from Xpc-/- mice were exclusively well or moderately well-differentiated squamous cell carcinomas. In Xpc+/+ and Xpc+/- mice, many of the squamous cell carcinomas were less well differentiated. We also documented previously increased predisposition to UV radiation-induced skin cancers in Xpc-/- Apex+/- mice. Here we show the absence of mutations in the cDNA of the remaining Apex allele, a further suggestive indication of haploinsufficiency and its resulting predisposition to skin cancer. The Trp53 and Apex heterozygous conditions altered the skin tumor spectrum to more poorly differentiated forms in all Xpc genotypes.     

Inherited germline TP53 mutation encodes a protein with an aberrant C-terminal motif in a case of pediatric adrenocortical tumor

Childhood adrenocortical tumor (ACT), a very rare malignancy, has an annual worldwide incidence of about 0.3 per million children younger than 15 years. The association between inherited germline mutations of the TP53 gene and an increased predisposition to ACT was described in the context of the Li-Fraumeni syndrome. In fact, about two-thirds of children with ACT have a TP53 mutation. However, less than 10% of pediatric ACT cases occur in Li-Fraumeni syndrome, suggesting that inherited low-penetrance TP53 mutations play an important role in pediatric adrenal cortex tumorigenesis. We identified a novel inherited germline TP53 mutation affecting the acceptor splice site at intron 10 in a child with an ACT and no family history of cancer. The lack of family history of cancer and previous information about the carcinogenic potential of the mutation led us to further characterize it. Bioinformatics analysis showed that the non-natural and highly hydrophobic C-terminal segment of the frame-shifted mutant p53 protein may disrupt its tumor suppressor function by causing misfolding and aggregation. Our findings highlight the clinical and genetic counseling dilemmas that arise when an inherited TP53 mutation is found in a child with ACT without relatives with Li-Fraumeni-component tumors.     

Impact of ionizing radiation and genetic background on mammary tumorigenesis in p53-deficient mice

Loss of p53 function is known to compromise cell cycle regulation, inductionof apoptosis, and DNA damage repair and can facilitate neoplastic transformation of cells. Mutations in the p53 gene are identified frequently in breast carcinomas. Li-Fraumeni patients inheriting a mutant p53 allele have an increased risk for developing tumors including breast cancer. Although mouse lines carrying mutations in the p53 gene have been generated, they die primarily of lymphoma and thus to date provide a limited model for the study of this disease and the role of p53 in nonfamilial breast cancer. An increasing body of literature suggests that the incidence of various tumors is determined largely by the genetic background on which mutations are studied. In addition, population studies and studies in animals suggest that environmental factors, together with genetic factors, determine overall risk for development of specific types of tumors. We therefore examined the impact of genetic background together with exposure to ionizing radiation on the development of tumors, particularly mammary tumors, in p53-deficient animals. We report here that modifier alleles present in the BALB/c strain increase the incidence of hemangiosarcomas [15 of 53 (28.3%); P = 0.0007] in p53(-/-) mice above rates reported previously in p53(-/-) mice on a mixed background as compared to the incidence observed in DBA/p53(-/-) mice. However, no increase in the frequency of mammary tumors is seen in these mice or in p53(-/-) DBA/2 animals, nor was an increase in mammary tumors observed in the DBA/2 p53(+/-) mice, even after exposure to 5 Gy of whole-body ionizing radiation. In contrast, a significant increase in the incidence of mammary tumors was observed in similarly treated BALB/c p53(+/-) mice (37.3% versus 6.8%; P = 0.0007). This was accompanied by a comparable decrease in the incidence of lymphomas. These results show that environmental agents together with genetic factors can increase the frequency and decrease the latency of mammary tumors, leading to an incidence similar to that observed in Li-Fraumeni syndrome. Furthermore, it suggests that the risk of development of a particular type of tumor by individuals deficient in p53 after exposure to damaging agents can be influenced by modifier alleles.