Oncovirus-induced permanent genetic instability in Drosophila melanogaster

Mutant alleles of a system of genetic instability induced by oncoviral DNAs were shown to demonstrate an unstable manifestation 500 generations after their emergence. A cytogenetic analysis of oncovirus-induced unstable lines has revealed numerous chromosome rearrangements. For the Lobe alleles of this system, a specific chromosome rearrangement, Df(2L) = 35C-36B, was found on the left arm of chromosome 2. We used recessive lethal mutations involving DNA rearrangements in a successful construction of cross systems for "explosive" instability.     

Induction of unstable mutations in Drosophila melanogaster by microinjection of oncogenic virus DNA into the embryo polar plasma. Insertional nature of mutations]

We have demonstrated that mutations induced in Drosophila melanogaster by the microinjections of adenovirus Sa7 DNA in early embryos are of insertional nature. The role of insertional elements is played by the Drosophila transposons, but not by the virus DNA. The ability of oncoviral DNA to induce transpositions of mobile elements in recipient genome is the molecular basis of this system of genetic instability.     

High incidence of mosaic mutations induced by irradiating paternal germ cells of the medaka fish, Oryzias latipes.

Delayed-type mutations induced by radiation have recently been demonstrated in various somatic-cell systems. Such mutations are thought to result from the transmission of genetic instability through many cell divisions subsequent to a single exposure to ionizing radiation. Here, we have examined whether 'transgenerational' delayed-type mutations can arise during embryonic development of the medaka fish as a result of exposing the sperm and spermatids of live fish to 137Cs gamma-radiation. To do this, we made use of a sensitive specific-locus test (SLT) for the medaka that we have recently developed. Because the medaka has a transparent egg membrane and embryo body, both visible mosaics and whole-body mutations can be detected during development at an early-expressed pigmentation locus. When wild-type +/+ males were gamma-irradiated and then mated with wl/wl females, the frequency of F1 embryos with both wild-type orange leucophores (wl/+) and mutant-type white leucophores (wl/wl*) (mosaic mutants) was about 5.7x10(-3)/Gy. The frequency of embryos with only white leucophores (whole-body mutants) was about 1.3x10(-3)/Gy. These results suggest that delayed mutations frequently arise in medaka fish embryos that have been fertilized with irradiated sperm. Some possible mechanisms involved in the generation of these delayed mutational events (including genomic instability in the early embryos) are discussed.     

Role of induced genetic instability in the mutagenic effects of chemicals and radiation

Recent studies have demonstrated that cells exposed to ionizing radiation or alkylating agents can develop prolonged genetic instability. Induced genetic instability is manisested in multiple ways, including delayed reproductive death, an increased rate of point mutations, and an increased rate of chromosome rearrangements. In many respects these changes are similar to the genetic instability associated with cancer and some human genetic diseases. Therefore, as with cancer cells, multiple mechanisms may be involved, some occuring in the early stages and some in the later stages. The high percentage of cells that develop induced genetic instability after exposure to stress, and the prolonged period over which the instability occurs, indicates that the instability is not in response to residual damage in the DNA or mutations in specific genes. Instead, changes affecting most of the exposed cells, such as epigenetic alterations in gene expression or chain reactions of chromosome rearrangements, are a more likely explanation. Learning more about the mechanisms involved in this process is essential for understanding the consequences of exposure of cells to ionizing radiation or alkylating agents.     

Glucocerebrosidase mutations in Gaucher disease.

BACKGROUND: Thirty-six mutations that cause Gaucher disease, the most common glycolipid storage disorder, are known. Although both alleles of most patients with the disease contain one of these mutations, in a few patients one or both disease-producing alleles have remained unidentified. Identification of mutations in these patients is useful for genetic counseling. MATERIALS AND METHODS: The DNA from 23 Gaucher disease patients in whom at least one glucocerebrosidase allele did not contain any of the 36 previously described mutations has been examined by single strand conformation polymorphism (SSCP) analysis, followed by sequencing of regions in which abnormalities were detected. RESULTS: Eight previously undescribed mutations were detected. In exon 3, a deletion of a cytosine at cDNA nt 203 was found. In exon 6, three missense mutations were identified: a C-->A transversion at cDNA nt 644 (Ala176-->Asp), a C-->A transversion at cDNA nt 661 that resulted in a (Pro182-->Thr), and a G-->A transition at cDNA nt 721 (Gly202-->Arg). Two missense mutations were found in exon 7: a G-->A transition at cDNA nt 887 (Arg257-->Gln) and a C-->T at cDNA nt 970 (Arg285-->Cys). Two missense mutations were found in exon 9: a T-->G at cDNA nt 1249 (Trp378-->Gly) and a G-->A at cDNA nt 1255 (Asp380-->Asn). In addition to these disease-producing mutations, a silent C-->G transversion at cDNA nt 1431, occurring in a gene that already contained the 1226G mutation, was found in one family. CONCLUSIONS: The mutations described here and previously known can be classified as mild, severe, or lethal, on the basis of their effect on enzyme production and on clinical phenotype, and as polymorphic or sporadic, on the basis of the haplotype in which they are found. Rare mutations such as the new ones described here are sporadic in nature.     

Heterogeneity of mutations in argininosuccinate synthetase causing human citrullinemia

Citrullinemia is an autosomal recessive disease caused by deficiency of argininosuccinate synthetase. In order to characterize mutations, RNA was isolated from cultured fibroblasts from 13 unrelated patients with neonatal citrullinemia. Ten mutations were identified by sequencing of amplified cDNA. Seven single base missense mutations were identified: Gly14----Ser, Ser180----Asn, Arg157----His, Arg304----Trp, Gly324----Ser, Arg363----Trp, and Gly390----Arg. Six of these missense mutations involved conversion of a CpG dinucleotide in the sense strand to TpG or CpA, and six of the seven mutations alter a restriction enzyme site in the cDNA. Two mutations were observed in which the sequences encoded by a single exon (exon 7 or 13) were absent from the cDNA. One mutation is a G----C substitution in the last position of intron 15 resulting in splicing to a cryptic splice site within exon 16. There is extreme heterogeneity of mutations causing citrulinemia. This heterogeneity may prove typical for less common autosomal recessive human genetic diseases.     

Interphase cytogenetics in estimation of genomic mutations in somatic cells

The review considers the current state, possibilities, and perspectives of using interphase cytogenetics in the estimation of genomic mutations in human and animal somatic cells for aims of genetic toxicology and genetic instability analysis. Possible mechanisms underlying action of mutagens causing numeric chromosome aberrations are discussed.     

The level of dysgenic sterility and recessive mutations induced in laboratory strains of Drosophila melanogaster exposed to chronic low-dose gamma irradiation

Recent investigations showed that genetic instability accounts for many radiobiological effects. However, mechanisms underlying this phenomenon are still poorly understood. Assuming that mobile genetic elements may be involved in the induction of genetic instability, we studied parameters that characterize the activity of these elements in Drosophila melanogaster: hybrid dysgenesis and the level of recessive lethal mutations. In our experiments, we used D. melanogaster strains that differed in the type of hybrid dysgenesis (P-M and H-E). It was demonstrated that chronic exposure to radiation leads to substantial changes in the genetic structure of a population and an enhanced level of dysgenic sterility. Our results indicate that genetic instability and adaptation to the effect of chronic gamma-radiation are associated with the radiation-induced mobilization of mobile genetic elements.     

Microsatellite instability and mutations of p53 and TGF-‚ RII genes in gastric cancer

To investigate the molecular mechanism of gastric carcinogenesis, we analyzed genetic instability and p53 gene mutations in 40 primary gastric carcinomas. Tumor samples were from untreated patients with no family history suggestive of genetic predisposition to cancer. We screened six microsatellite loci by the polymerase chain reaction (PCR) method, and exons 5–8 of the p53 gene by the PCR-based denaturing gradient gel electrophoresis and sequencing techniques. Microsatellite instability was detected in 32.5% (13/40), and gene mutations in 40% (16/40), of the tumors analyzed. No statistically significant associations were found between genetic alterations and clinico-pathological variables (with the exception of diffusion of lymph node metastases, which was inversely associated with the presence of microsatellite alterations; P < 0.01). Interestingly, a negative association was found between genetic instability and p53 gene mutations: 11 out of 13 tumors showing instability proved to carry a nonmutated p53 gene versus 2/13 carrying a mutated gene (P = 0.03). These observations suggest that genetic instability and p53 gene mutations play a crucial role in the gastric carcinogenic process, but likely act through distinct pathways during cancer development. However, genetic instability is not in and of itself neoplastic. Therefore, we investigated whether insertion/deletion mutations of the polyadenine tract within the transforming growth factor-β type II receptor gene (TGF-βRII) were frequently present in gastric tumors with an RER+ (replication error) phenotype. We found RII mutations in 8/40 (20%) samples: mutations were present in 7/13 (54%) RER+ tumors versus 1/27 (4%) RER– cases (P < 0.001). Received: 14 May 1996 / Revised: 13 June 1996     

Mutations in the APC tumour suppressor gene cause chromosomal instability

Two forms of genetic instability have been described in colorectal cancer: microsatellite instability and chromosomal instability. Microsatellite instability results from mutations in mismatch repair genes; chromosomal instability is the hallmark of many colorectal cancers, although it is not completely understood at the molecular level. As truncations of the Adenomatous Polyposis Coli (APC) gene are found in most colorectal tumours, we thought that mutations in APC might be responsible for chromosomal instability. To test this hypothesis, we examined mouse embryonic stem (ES) cells homozygous for Min (multiple intestinal neoplasia) or Apc1638T alleles. Here we show that Apc mutant ES cells display extensive chromosome and spindle aberrations, providing genetic evidence for a role of APC in chromosome segregation. Consistent with this, APC accumulates at the kinetochore during mitosis. Apc mutant cells form mitotic spindles with an abundance of microtubules that inefficiently connect with kinetochores. This phenotype is recapitulated by the induced expression of a 253-amino-acid carboxy-terminal fragment of APC in microsatellite unstable colorectal cancer cells. We conclude that loss of APC sequences that lie C-terminal to the beta-catenin regulatory domain contributes to chromosomal instability in colorectal cancer.     

Phenylketonuria missense mutations in the Mediterranean.

Two missense mutations have been identified in the phenylalanine hydroxylase (PAH) genes of an Italian phenylketonuria (PKU) patient. Both mutations occurred in exon 7 of the PAH gene, resulting in the substitution of Trp for Arg at amino acid 252 (R252W) and of Leu for Pro (P281L) at amino acid 281 of the protein. Expression vectors containing either the normal human PAH cDNA or mutant cDNAs were constructed and transfected into cultured mammalian cells. Extracts from cells transfected with either mutant construct showed negligible enzyme activity and undetectable levels of immunoreactive PAH protein as compared to the normal construct. These results are compatible with the severe classical PKU phenotype observed in this patient. Population genetic studies in the Italian population revealed that both the R252W and the P281L mutations are in linkage disequilibrium with mutant restriction fragment length polymorphism (RFLP) haplotype 1, which is the most prevalent RFLP haplotype in this population. The R252W mutation is present in 10% and the P281L mutation is present in 20% of haplotype 1 mutant chromosomes. These mutations are both very rare among other European populations, suggesting a Mediterranean origin for these mutant chromosomes.     

The nature of spontaneous and induced mutagenesis in a genetically unstable mutator strain of Drosophila melanogaster]

The spontaneous and induced frequencies of visible mutations by N-nitroso-N-ethylurea in male cells of Drosophila melanogaster genetically unstable mutator strain have been investigated. The spontaneous and induced by N-nitroso-N-ethylurea genetic instability in mutator strain have similar manifestation, that evidently testifies the existence of general mechanisms of the appearance of unstable mutations, namely the transpositions of the mobile genetic elements.     

The contribution of endogenous sources of DNA damage to the multiple mutations in cancer

There is increasing evidence that most human cancers contain multiple mutations. By the time a tumor is clinically detectable it may have accumulated tens of thousands of mutations. In normal cells, mutations are rare events occurring at a rate of 10(-10) mutations per nucleotide per cell per generation. We have argued that the mutation rates exhibited by normal human cells are insufficient to account for the large number of mutations found in human cancers, and therefore, that an early event in tumorigenesis is the development of a mutator phenotype. In normal cells, spontaneous and induced DNA damage is balanced by multiple pathways for DNA repair, and most DNA damage is repaired without error. However, in tumor cells this balance may be shifted such that damage overwhelms the repair capacity, resulting in the accumulation of multiple mutations. Our hypothesis is that multiple random mutations occur during carcinogenesis. The sequential mutations that are observed in some human tumors result from selective events required for tumor progression. We consider the possibility that endogenous sources of DNA damage, in particular oxidative DNA damage, may contribute to genomic instability and to a mutator phenotype in some tumors. Endogenous and environmental sources of reactive oxygen species (ROS) are abundant. In tumor cells, antioxidant or DNA repair capacity may be insufficient to compensate for the production of ROS, and these endogenous ROS may be capable of damaging DNA and inducing mutations in critical DNA stability genes. The possibility that oxidative DNA damage could be a significant source of the genomic instability characteristic of human cancers is exciting, because it may be feasible to modulate the extent of oxidative damage through antioxidant therapy. The use of antioxidants to reduce the extent of molecular damage by ROS could delay the progression of cancer.     

Interphase cytogenetics in estimation of genomic mutations in somatic cells

The review considers the current state, possibilities, and perspectives of using interphase cytogenetics in the estimation of genomic mutations in human and animal somatic cells for aims of genetic toxicology and genetic instability analysis. Possible mechanisms underlying action of mutagens causing numeric chromosome aberrations are discussed.Translated from Genetika, Vol. 41, No. 1, 2005, pp. 5–16.Original Russian Text Copyright © 2005 by Timoshevsky, Nazarenko.     

Induction of unstable mutations in Drosophila melanogaster by microinjection of DNA from oncogenic viruses into the embryo polar plasma. II. Analysis of the role of injected DNA

We have demonstrated that the mutagenic effect of oncovirus DNA injected into Drosophila embryos is of two-type locus specificity: the spectrum of mutations induced by the retroviral cDNA (RSV) changed in different recipient stocks and those induced by the adenoviral DNA (Sa7) did not differ in the stocks studied. The Sa7 DNA and the cDNA of RSV induce mutations in different groups of loci. Transpositions of the copia element were found in mutant lines obtained in both cases.     

Different point mutations in the met oncogene elicit distinct biological properties.

The MET proto-oncogene, encoding the tyrosine kinase receptor for HGF, controls genetic programs leading to cell growth, invasiveness, and protection from apoptosis. Recently, MET mutations have been identified in hereditary and sporadic forms of papillary renal carcinoma (PRC). Introduction of different naturally occurring mutations into the MET cDNA results in the acquisition of distinct biochemical and biological properties of transfected cells. Some mutations result in a high increase in tyrosine kinase activity and confer transforming ability in focus forming assays. These mutants hyperactivate the Ras signaling pathway. Other mutations are devoid of transforming potential but are effective in inducing protection from apoptosis and sustaining anchorage-independent growth. These Met(PRC) receptors interact more efficiently with the intracellular transducer Pi3Kinase. The reported results show that MET(PRC) mutations can be responsible for malignant transformation through different mechanisms, either by increasing the growth ability of cells or by protecting cells from apoptosis and allowing accumulation of other genetic lesions.-Giordano, S., Maffe, A., Williams, T. A., Artigiani, S., Gual, P., Bardelli, A., Basilico, C., Michieli, P., Comoglio, P. M. Different point mutations in the met oncogene elicit distinct biological properties.     

Estrogen, DNA damage and mutations

Estrogen administration to rodents results in various types of DNA damage and ultimately leads to tumors in estrogen-responsive tissues. Yet these hormones have been classified as nonmutagenic, because they did not induce mutations in classical bacterial and mammalian mutation assays. In this review, we have discussed the induction by estrogens of DNA and chromosomal damage and of gene mutations, because the classical assays were designed to uncover mutations only at one specific locus and could not have detected other types of mutations or changes in other genes. Various types of estrogen-induced DNA damage include: (a) direct covalent binding of estrogen quinone metabolites to DNA; (b) enhancement of endogenous DNA adducts by chronic estrogen exposure of rodents; (c) free radical generation by metabolic redox cycling between quinone and hydroquinone forms of estrogens and free radical damage to DNA such as strand breakage, 8-hydroxylation of purine bases of DNA and lipid hydroperoxide-mediated DNA modification. Two different types of chromosomal damage have also been induced by estrogen in vivo and in cells in culture such as numerical chromosomal changes and also structural chromosomal aberrations. Gene mutations have been induced in several cell types in culture either by the parent estrogen or by reactive estrogen quinone metabolites. Furthermore, in estrogen-induced kidney tumors in hamsters, several mutations have been observed in the DNA polymerase beta gene mRNA. Estradiol also induces microsatellite instability in these kidney tumors and in premalignant kidney exposed to estradiol. Although this work is still ongoing, it can be concluded that estrogens are complete carcinogens capable of tumor initiation by mutation potentially in critical genes. The hormonal effects of estrogens may complete the development of tumors.