The mutational spectra of gene p53 in different types of tumors]

The comparative analysis of the frequencies of nucleotide exchanges in mutational spectra of gene p53 (5-8 exons) between germline cancer-prone families (Li-Fraumeni syndrome), between somatic mutations in the tumors of different histogenesis and cell lines, obtained from them, was carried out. The nucleotide positions with high level of mutation events (mutational "hot spots"), typical for germline mutational spectra, tissue-specific patterns of their disappearing and appearing of new ones in solid tumors in vivo, nearly complete absence of "hot spots" in lymphomas and cell lines in vitro were revealed. The obtained results allowed to suggest, that one of the leading factor controlling hot-spots distribution in 5-8 exons of gene p53 is the specificity of cell division conditions in vivo and in vitro.     

Further studies with a cell immortalization assay to investigate the mutation signature of aristolochic acid in human p53 sequences

To test hypotheses on the origins of p53 mutations in human tumors, novel strategies are needed for generating mutation spectra experimentally. To this end we developed an assay employing Hupki (Human p53 knock-in) mouse embryonic fibroblasts (HUFs). Here we examine p53 mutations induced by aristolochic acid I (AAI)), the carcinogen probably responsible for Chinese herbal nephropathy. Six immortalized cultures (cell lines) from 18 HUF primary cultures exposed at passage 1 for 48 h to 50 microM AAI harbored p53 mutations in the human DNA binding domain sequence of the Hupki p53 tumor suppressor gene. The most frequently observed mutation was A to T transversion, corroborating our previous mutation study with AAI, and consistent with the presence of persistent AAI-adenine adducts found both in DNA of exposed patients and in DNA of AAI-exposed HUF cells. One of the mutations was identical in position (codon 139) and base change (A to T on the non-transcribed strand) to the single p53 mutation that has thus far been characterized in a urothelial tumor of a nephropathy patient with documented AAI exposure. Of the seven p53 mutations identified thus far in >60 HUF cell lines that immortalized spontaneously (no carcinogen treatment), none were A:T to T:A transversions. In addition, no A to T substitutions were identified among the previously reported set of 18 mutations in HUF cell lines derived from B(a)P treatment in which transversions at G:C base pairs predominated.     

Mutational hotspots in the TP53 gene and, possibly, other tumor suppressors evolve by positive selection

Background  

The mutation spectra of the TP53 gene and other tumor suppressors contain multiple hotspots, i.e., sites of non-random, frequent mutation in tumors and/or the germline. The origin of the hotspots remains unclear, the general view being that they represent highly mutable nucleotide contexts which likely reflect effects of different endogenous and exogenous factors shaping the mutation process in specific tissues. The origin of hotspots is of major importance because it has been suggested that mutable contexts could be used to infer mechanisms of mutagenesis contributing to tumorigenesis.     

Expression of wild-type p53 is not compatible with continued growth of p53-negative tumor cells.

Inactivation of the cellular p53 gene is a common feature of Friend virus-induced murine erythroleukemia cell lines and may represent a necessary step in the progression of this disease. As well, frequent loss or mutation of p53 alleles in diverse human tumors is consistent with the view of p53 as a tumor suppressor gene. To examine the significance of p53 gene inactivation in tumorigenesis, we have attempted to express transfected wild-type p53 in three p53-negative tumor cell lines: murine DP16-1 Friend erythroleukemia cells, human K562 cells, and SKOV-3 cells. We found that aberrant p53 proteins, which differ from wild-type p53 by a single amino acid substitution, were expressed stably in these cells, whereas wild-type p53 expression was not tolerated. The inability of p53-negative tumor cell lines to support long-term expression of wild-type p53 protein is consistent with the view that p53 is a tumor suppressor gene.     

A Novel p53 Mutant Found in Iatrogenic Urothelial Cancers Is Dysfunctional and Can Be Rescued by a Second-site Global Suppressor Mutation

Exposure to herbal remedies containing the carcinogen aristolochic acid (AA) has been widespread in some regions of the world. Rare A→T TP53 mutations were recently discovered in AA-associated urothelial cancers. The near absence of these mutations among all other sequenced human tumors suggests that they could be biologically silent. There are no cell banks with established lines derived from human tumors with which to explore the influence of the novel mutants on p53 function and cellular behavior. To investigate their impact, we generated isogenic mutant clones by integrase-mediated cassette exchange at the p53 locus of platform (null) murine embryonic fibroblasts and kidney epithelial cells. Common tumor mutants (R248W, R273C) were compared with the AA-associated mutants N131Y, R249W, and Q104L. Assays of cell proliferation, migration, growth in soft agar, apoptosis, senescence, and gene expression revealed contrasting outcomes on cellular behavior following introduction of N131Y or Q104L. The N131Y mutant demonstrated a phenotype akin to common tumor mutants, whereas Q104L clone behavior resembled that of cells with wild-type p53. Wild-type p53 responses were restored in double-mutant cells harboring N131Y and N239Y, a second-site rescue mutation, suggesting that pharmaceutical reactivation of p53 function in tumors expressing N131Y could have therapeutic benefit. N131Y is likely to contribute directly to tumor phenotype and is a promising candidate biomarker of AA exposure and disease. Rare mutations thus do not necessarily point to sites where amino acid exchanges are phenotypically neutral. Encounter with mutagenic insults targeting cryptic sites can reveal specific signature hotspots.     

Point mutation of the p53 gene resulting in splicing inhibition in small cell lung carcinoma

The p53 gene is functionally inactivated mostly by point mutations resulting in amino acid substitutions in a wide variety of human cancers. We found a novel mutation of the p53 gene in a small cell lung carcinoma cell line, Lu-143. One of the allelic p53 genes was lost accompanied by loss of heterozygosity for chromosome 17. In the remaining allelic p53 gene, there was a single-base substitution of G to T at position 1 within the splice donor site of intron 7, and the mutated intron was not spliced out during the mRNA maturation process. As a result of this mutation, larger sized p53 mRNA was expressed and no p53 specific protein was detected in this cell line. These results suggest that mutations causing splicing abnormalities are one of the molecular mechanisms for the p53 gene inactivation in human cancer.     

Mutations and selection in the generation of class II histocompatibility antigen polymorphism.

A comparison of seven human DR and DC class II histocompatibility antigen beta-chain amino acid sequences indicates that the allelic variation is of comparable magnitude within the DR and DC beta-chain genes. Silent and replacement nucleotide substitutions in six DR and DC beta-chain sequences, as well as in seven murine class II sequences (three I-A beta and four I-A alpha alleles) were analyzed. The results suggest that the mutation rates are of a comparable magnitude in the nucleotide sequences encoding the first and second external domains of the class II molecules. Nevertheless, the allelic amino acid replacements are predominantly located in the first domains. We conclude that a conservative selective pressure acts on the second domains, whereas in many positions in the first domains replacement substitutions are selectively neutral or maybe even favoured. Thus, the difference between the first and second domains as regards the number of amino acid replacements is mainly due to selection.     

p53 mutations in tumors derived from irradiated human thyroid epithelial cells

A non-tumorigenic human thyroid epithelial cell line (HTori-3) has been transformed into tumorigenic cells by exposure in vitro to alpha particles or gamma-radiation. These transformants were tumorigenic in athymic nude mice and tumors were transplantable into other nude mice. To further characterize processes involved in neoplastic progression, the tumor cell lines derived from these radiation-induced primary tumors were screened for mutations in the p53 tumor suppressor gene. p53 mutation was detected by single-strand conformation polymorphism (SSCP) analysis of exons 5 to 8 inclusive. Mutations detected by SSCP analysis were confirmed by sequencing. Mutations were detected in all four exons analysed, although there was no correlation between dose, LET or mutation position or frequency. Mutations in p53 exons 6 and 7 have been reported in the childhood papillary thyroid carcinomas in Belarus presumably as a result of radioiodine fall-out. Similarly here, p53 mutations are induced experimentally during the development of human thyroid tumors generated by irradiation of a human thyroid epithelial cell line in vitro.     

Alterations of the p53 gene in Epstein-Barr virus-associated immunodeficiency-related lymphomas.

Mutations of the p53 tumor suppressor gene are among the most common genetic alterations found in many different human malignancies, including those of the colon, lung, and breast. Alterations in wild-type p53 lead to loss of the suppressor function and thus contribute to tumorigenesis. The potential role of p53 mutations in a sampling of B-cell lymphomas, the majority of which were associated with Epstein-Barr virus (EBV), was investigated. Twenty-six biopsy specimens from immunocompromised patients, including allograft recipients and patients with AIDS, Wiscott-Aldrich syndrome, and human T-cell leukemia virus type 1 infection, in comparison with three Burkitt lymphomas and four Burkitt lymphoma cell lines were analyzed. Mutation in p53 was detected in all four Burkitt lymphoma cell lines as well as the three Burkitt lymphoma biopsy specimens. In patients with AIDS, 5 of 10 lymphomas were EBV positive, and 1 had a mutation in p53. Mutation in p53 was not detected in 14 EBV-positive lymphomas which arose in transplant recipients. These data indicate that with the exception of Burkitt lymphomas, p53 mutations are not involved in the majority EBV-positive B-cell lymphomas which develop in immunocompromised patients.     

Mutations in p53 cDNA sequence introduced by retroviral vector

The high mutation rates of retroviruses are a potential problem with retroviral vectors. We studied the mutation rates and spectra of p53 sequences transduced with a retroviral vector in a cancer gene therapy model. When p53-deficient H358 non-small cell lung cancer cells were treated with a retroviral vector carrying normal p53 cDNA, most of transduced cells were killed by apoptosis. However, a small number of clones escaped p53-mediated apoptosis. We examined the p53 cDNA structure in these resistant clones. PCR-based analysis showed that 88/102 clones had detectable mutations in p53, including gross rearrangements, deletions/insertions, and base substitutions. To study the mutation rate of the p53 sequence in all transduced clones, the retroviral vector containing the non-functional p53 gene and the Neo-resistant marker gene was introduced into H358 cells. Only one of 95 isolated clones showed a base substitution. These results indicate that the mutation rate of p53 is not particularly high, but there is a significant risk that cancer cells will resist p53 gene therapy as a result of retroviral replication errors.     

Comparison of the Ames test and a newly developed assay for detection of mutagenic pollution of marine environments

Mismatch repair (MMR) genes, such as Msh2, are classified as "mutator" genes, responsible for the microsatellite instability identified in many tumors. In the current study, the mutation frequency and mutational spectrum in thymic lymphoma arising in Msh2 deficient mice are investigated. Thymic lymphoma developed in Msh2-/- background displayed an eight to nine-fold increase in mutation frequency compared to the normal thymi in Msh2 deficient animals. Sequencing demonstrated significantly different mutational spectra between normal thymus tissue and thymic lymphomas in Msh2-/- mice (P=0.02). The tumor mutational spectrum is characterized by an increase in base substitutions occurring at A:T sites, and multiple mutations, as well as a minor increase in -1 frameshifts. We analyzed mutations in different parts of the tumors, and different regional hotspots could be identified. Several hotspot mutations that are a rare event in normal tissues were identified in the tumor tissues. We conclude that thymic lymphomas arising in Msh2 deficient genetic background are hypermutable and the altered mutational spectrum might be an indication of infidelity of DNA replication during tumorigenesis.     

Dominant-negative features of mutant TP53 in germline carriers have limited impact on cancer outcomes

Germline TP53 mutations result in cancer proneness syndromes known as Li-Fraumeni, Li-Fraumeni-like, and nonsyndromic predisposition with or without family history. To explore genotype/phenotype associations, we previously adopted a functional classification of all germline TP53 mutant alleles based on transactivation. Severe deficiency (SD) alleles were associated with more severe cancer proneness syndromes, and a larger number of tumors, compared with partial deficiency (PD) alleles. Because mutant p53 can exert dominant-negative (DN) effects, we addressed the relationship between DN and clinical manifestations. We reasoned that DN effects might be stronger in familial cancer cases associated with germline TP53 mutations, where mutant alleles coexist with the wild-type allele since conception. We examined 104 p53 mutant alleles with single amino acid substitutions described in the IARC germline database for (i) transactivation capability and (ii) capacity to reduce the activity of the wild-type allele (i.e., DN effect) using a quantitative yeast-based assay. The functional classifications of p53 alleles were then related to clinical variables. We confirmed that a classification based on transactivation alone can identify familial cancer cases with more severe clinical features. Classification based on DN effects allowed us to highlight similar associations but did not reveal distinct clinical subclasses of SD alleles, except for a correlation with tumor tissue prevalence. We conclude that in carriers of germline TP53 mutations transactivation-based classification of TP53 alleles appears more important for genotype/phenotype correlations than DN effects and that haplo-insufficiency of the TP53 gene is an important factor in cancer proneness in humans.     

Ineffectiveness of the presence of H-ras/p53 combination of mutations in squamous cell carcinoma cells to induce a conversion of a nontumorigenic to a tumorigenic phenotype

Human tumor cells have properties in vitro or in surrogate hosts that are distinct from those of normal cells, such as immortality, anchorage independence, and tumor formation in nude mice. However, different cells from individual tumors may exhibit some, but not all of these features. In previous years, human tumor cell lines derived from different tumor and tissue types have been studied to determine those molecular changes that are associated with the in vitro properties listed above and with tumorigenicity in nude mice. In the present study, seven cell lines derived from human tumors were characterized for p53 and ras mutations that may occur in SCC tumor phenotypes and for tumor formation in nude mice. This investigation was designed to examine whether co-occurrence of mutated ras and p53 lead to a malignant stage in the progression process. None of the seven cell lines contained mutations in the recognized "hot spots" of the p53 tumor suppressor gene, but four had a nonsense/splice mutation in codon 126 and a mutation in codon 12 of the H-ras gene. The remaining three cell lines had p53 mutations in intron 5, in codon 193, and a missense mutation in codon 126, respectively. Four of seven cell lines were nontumorigenic; two of these cell lines contained a nonsense p53-126 mutation and mutated ras; one had a missense mutation at codon 126 but no mutated ras; the the fourth had only a p53 mutation at codon 193. Two of the nontumorigenic cell lines were converted to tumorigenicity after treatment with methyl methanesulfonate or N-methyl-N-nitro-N-nitrosoguanidine with no apparent additional mutations in either gene. Our analysis revealed that there was a high frequency of genetic diversity and mutations in both p53 and H-ras. There was also a lack of a causal relationship in the presence of mutations in p53 and the cells ability to exhibit a malignant potential in nude mice.     

Glutathione S-transferase GSTM1, GSTT1 and p53 codon 72 polymorphisms in human tumor cells

The genes of the glutathione S-transferase (GST) family encode enzymes that appear to be critical in cellular protection against the cytotoxic effects, whereas p53 is a tumor suppressor gene. Despite a large number of studies on germline polymorphisms of GSTM1, GSTT1 and p53 genes, there have been very few reports on genotyping of these genes in human malignant tumor cells. In this study, we investigated GSTM1, GSTT1 and p53 codon 72 polymorphisms in a variety of human tumor cell lines originating from different organs to clarify tissue-specific polymorphic frequency of these genes in human solid tumors. The GSTM1 and GSTT1 genetic polymorphisms were evaluated using multiplex PCR techniques and PCR-RFLP analysis was conducted to identify p53 codon 72 genotypes. Gene expression of GSTM1 or GSTT1 was detected by RT-PCR in the cells with respective present genotype for each. Polymorphisms of p53 codon 72 detected by PCR-RFLP were also confirmed using SSCP and sequence analyses. GSTM1 and GSTT1 genotypes were various in 104 cell lines examined. Null GSTM1 genotype was dominant in small cell lung, kidney and ovarian carcinoma cells, whereas null GSTT1 genotype was dominant in cervical and endometrial carcinoma cells. GSTM1 and GSTT1 genotypes in ovarian carcinoma cells were quite similar to those in small cell lung carcinoma cells. Polymorphic frequency of p53 codon 72 was also various among the cells, however, the Pro allele was found in only 1 of 6 kidney, 14 cervical and 4 endometrial carcinoma cell lines. There was a significant difference in GSTM1 and p53 genotypes between 34 small cell and 24 non small cell lung carcinoma cells (P < 0.01). Combined study on the distribution of GSTM1, GSTT1 and p53 genotypes revealed that null GSTM1 genotype was associated with the Arg allele of p53 codon 72 in 58 lung carcinoma cells and null GSTT1 genotype was associated with the Pro/Pro homozygote in 104 tumor cell lines examined. This is the first study examining GSTM1, GSTT1 and p53 codon 72 polymorphisms in a variety of human solid tumor cells and suggesting that polymorphic frequency of these genes may be tissue- and organ-specific. The molecular interaction between GST gene defects and p53 codon 72 genotype in the development of human malignant tumors should be further investigated.     

Inheritance of R337H p53 gene mutation in children with sporadic adrenocortical tumor.

Adrenocortical tumors (ACTs) are frequent in Brazil. The mechanisms of adrenal tumorigenesis remain poorly established; the R337H germline mutation in the p53 gene has previously been associated with ACTs in Brazilian children. We investigated the frequency and inheritance of R337H p53 mutation as well as genotype and phenotype correlation in 21 children and 5 adult patients with ACTs. DNA was extracted from peripheral blood cells and/or tumor tissue for sequencing exon 10 of the p53 gene. Nine sets of parents of patients with p53 mutation were also submitted to mutational analysis. Virilization was the most common clinical sign in children with or without Cushing's syndrome. Two members of the adult group showed asymptomatic adrenal incidentalomas, two showed virilization, and one presented with Cushing's syndrome. Sixteen children with ACTs had peripheral blood available, and twelve of them (75%) showed the heterozygous R337H p53 gene mutation. The R337H mutation was found in fifteen samples of the nineteen tumor specimens available (78.9%). Among the nine sets of parents of the patients with R337H mutation, eight showed the same mutation with heterozygosity in one of the parents. None of the parents showed ACTs or any other neoplasia at the time of the study. Only one adult patient with an ACT revealed the same R337H p53 germline mutation. There was no association between the presence of germline or tissue R337H p53 mutation and malignancy at diagnosis. We confirmed the high frequency of R337H p53 mutation in Brazilian children with sporadic ACTs. The R337H p53 mutation was inherited from one of the parents of the patients, and there was no association between the presence of this mutation and tumor malignancy in children. The founder effect of R337H p53 mutation and the role of environmental mutagens contributing to the geographical clustering and high prevalence of ACTs in Brazilian children remain to be established.     

Mutant p53 reactivation by small molecules makes its way to the clinic

The TP53 tumor suppressor gene is mutated in many human tumors, including common types of cancer such as colon and ovarian cancer. This illustrates the key role of p53 as trigger of cell cycle arrest or cell death upon oncogenic stress. Most TP53 mutations are missense mutations that result in single amino acid substitutions in p53 and expression of high levels of dysfunctional p53 protein. Restoration of wild type p53 function in such tumor cells will induce robust cell death and allow efficient eradication of the tumor. Therapeutic targeting of mutant p53 in tumors is a rapidly developing field at the forefront of translational cancer research. Various approaches have led to the identification of small molecules that can rescue mutant p53. These include compounds that target specific p53 mutations, including PK083 and PK5174 (Y220C mutant p53) and NSC319726 (R175H mutant p53), as well as PRIMA-1 and its analog APR-246 that affect a wider range of mutant p53 proteins. APR-246 has been tested in a Phase I/II clinical trial with promising results.