Comprehensive identification of mutations induced by heavy‐ion beam irradiation in Arabidopsis thaliana

Heavy‐ion beams are widely used for mutation breeding and molecular biology. Although the mutagenic effects of heavy‐ion beam irradiation have been characterized by sequence analysis of some restricted chromosomal regions or loci, there have been no evaluations at the whole‐genome level or of the detailed genomic rearrangements in the mutant genomes. In this study, using array comparative genomic hybridization (array‐CGH) and resequencing, we comprehensively characterized the mutations in Arabidopsis thaliana genomes irradiated with Ar or Fe ions. We subsequently used this information to investigate the mutagenic effects of the heavy‐ion beams. Array‐CGH demonstrated that the average number of deleted areas per genome were 1.9 and 3.7 following Ar‐ion and Fe‐ion irradiation, respectively, with deletion sizes ranging from 149 to 602 180 bp; 81% of the deletions were accompanied by genomic rearrangements. To provide a further detailed analysis, the genomes of the mutants induced by Ar‐ion beam irradiation were resequenced, and total mutations, including base substitutions, duplications, in/dels, inversions, and translocations, were detected using three algorithms. All three resequenced mutants had genomic rearrangements. Of the 22 DNA fragments that contributed to the rearrangements, 19 fragments were responsible for the intrachromosomal rearrangements, and multiple rearrangements were formed in the localized regions of the chromosomes. The interchromosomal rearrangements were detected in the multiply rearranged regions. These results indicate that the heavy‐ion beams led to clustered DNA damage in the chromosome, and that they have great potential to induce complicated intrachromosomal rearrangements. Heavy‐ion beams will prove useful as unique mutagens for plant breeding and the establishment of mutant lines.     

Different modifications by vanillin in cytotoxicity and genetic changes induced by EMS and H2O2 in cultured Chinese hamster cells.

The modifying effects of vanillin on the cytotoxicity and 6-thioguanine (6TG)-resistant mutations induced by two different types of chemical mutagens, ethyl methanesulfonate (EMS) and hydrogen peroxide (H2O2), were examined using cultured Chinese hamster V79 cells. The effects of vanillin on H2O2-induced chromosome aberrations were also examined. Vanillin had a dose-dependent enhancing effect on EMS-induced cytotoxicity and 6TG-resistant mutations, when cells were simultaneously treated with vanillin. The post-treatment with vanillin during the mutation expression time of cells after treatment with EMS also showed an enhancement of the frequency of mutations induced by EMS. However, vanillin suppressed the cytotoxicity induced by H2O2 when cells were post-treated with vanillin after H2O2 treatment. Vanillin showed no change in the absence of activity of H2O2 to induce mutations. Post-treatment with vanillin also suppressed the chromosome aberrations induced by H2O2. The differential effects of vanillin were probably due to the quality of mutagen-induced DNA lesions and vanillin might influence at least two different kinds of cellular repair functions. The mechanisms by which vanillin enhances or suppresses chemical-induced cytotoxicity, mutations and chromosome aberrations are discussed.     

Telomeres, interstitial telomeric repeat sequences, and chromosomal aberrations

Telomeres are specialized nucleoproteic complexes localized at the physical ends of linear eukaryotic chromosomes that maintain their stability and integrity. The DNA component of telomeres is characterized by being a G-rich double stranded DNA composed by short fragments tandemly repeated with different sequences depending on the species considered. At the chromosome level, telomeres or, more properly, telomeric repeats--the DNA component of telomeres--can be detected either by using the fluorescence in situ hybridization (FISH) technique with a DNA or a peptide nucleic acid (PNA) (pan)telomeric probe, i.e., which identifies simultaneously all of the telomeres in a metaphase cell, or by the primed in situ labeling (PRINS) reaction using an oligonucleotide primer complementary to the telomeric DNA repeated sequence. Using these techniques, incomplete chromosome elements, acentric fragments, amplification and translocation of telomeric repeat sequences, telomeric associations and telomeric fusions can be identified. In addition, chromosome orientation (CO)-FISH allows to discriminate between the different types of telomeric fusions, namely telomere-telomere and telomere-DNA double strand break fusions and to detect recombination events at the telomere, i.e., telomeric sister-chromatid exchanges (T-SCE). In this review, we summarize our current knowledge of chromosomal aberrations involving telomeres and interstitial telomeric repeat sequences and their induction by physical and chemical mutagens. Since all of the studies on the induction of these types of aberrations were conducted in mammalian cells, the review will be focused on the chromosomal aberrations involving the TTAGGG sequence, i.e., the telomeric repeat sequence that "caps" the chromosomes of all vertebrate species.     

Comparison of the levels of chromosome aberration and sister chromatid exchange induced by chemical mutagens in vitro

Dose dependencies of the induction of sister chromatid exchanges (SCEs) and chromosome aberrations were studied under in vivo exposure of mouse bone marrow cells to 5 alkylating agents. The efficacy of the induction of SCEs for all the substances was 20 to 60 times higher than that of the induction of chromosome aberrations. It was demonstrated that SCEs induced by chemical mutagens in vivo and in vitro are more sensitive tests than chromosome aberrations.     

Restriction fragment pattern analysis of HPRT mutations induced in rat-liver epithelial cells by alkylating and arylating agents.

Structural alterations in the hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene in genomic DNA of adult rat-liver (ARL) epithelial cells that were mutated by alkylating and arylating mutagens were studied by restriction enzyme fragment pattern (RFP) analysis. ARL cells were mutated with the direct-acting alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) or the activation-dependent arylating agents 7,12-dimethylbenz[a]anthracene (DMBA) and N-2-acetylaminofluorene (AAF). Alterations in the HPRT gene of at least 10 independent 6-thioguanine-resistant (TGr) clones mutated by each chemical were analyzed using 8 different restriction endonucleases; Hind III, EcoRI, BamHI, XbaI, Hae III, XhoI, MspI and PstI, and a full-length HPRT cDNA as a probe in molecular hybridization. Among the 10 MNNG-induced mutants, the RFPs obtained with most endonucleases displayed no changes, while an altered RFP was found in only one mutant using XbaI. None of the 10 DMBA-induced mutants displayed altered RFPs. Restriction analysis of the 10 AAF-induced mutants showed no abnormality in HPRT gene structure in most restriction digests, while altered RFPs were detected in one mutant using MspI and in two mutants with XbaI digestion. Overall, the studies reveal an absence of major DNA sequence changes in 26 of 30 induced mutants although the mutant phenotype of 4 of the TGr clones can be attributed to gross chromosomal changes or a point mutation at the restriction site. The absence of detectable alterations in the RFPs of the majority of the mutants is strongly suggestive of base substitution as the major molecular alteration underlying the mutant phenotype. The HPRT activity of 14 of 30 mutants was at least 5% of the wild-type level, which is consistent with a structural alteration in the gene product expressed as partial activity of the enzyme. Therefore, the data are interpreted as indicating that in the ARL cells, all 3 mutagens induced primarily localized alterations in base sequences in the HPRT gene together with a few mutations involving large sequence changes.     

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.     

Detection of mutations and DNA polymorphisms using whole genome Southern Cross hybridization.

We report a general method for the detection of restriction fragment length alterations associated with mutations or polymorphisms using whole genomic DNA rather than specific cloned DNA probes. We utilized a modified Southern Cross hybridization to display the hybridization pattern of all size-separated restriction fragments from wild-type Caenorhabditis elegans to all the corresponding fragments in a particular mutant strain and in a distinct C. elegans variety. In this analysis, almost all homologous restriction fragments are the same size in both strains and result in an intense diagonal of hybridization, whereas homologous fragments that differ in size between the two strains generate an off-diagonal spot. To attenuate the contribution of repeated sequences in the genome to spurious off-diagonal spots, restriction fragments from each genome were partially resected with a 3' or 5' exonuclease and not denatured, so that only the DNA sequences at the ends of these fragments could hybridize. Off-diagonal hybridization spots were detected at the expected locations when genomic DNA from wild-type was compared to an unc-54 mutant strain containing a 1.5 kb deletion or to a C. elegans variety that contains dispersed transposon insertions. We suggest that this modified Southern Cross hybridization technique could be used to identify restriction fragment length alterations associated with mutations or genome rearrangements in organisms with DNA complexities as large as 10(8) base pairs and, using rare-cutting enzymes and pulse-field gel electrophoresis, perhaps as large as mammalian genomes. This information could be used to clone fragments associated with such DNA alterations.     

Deletion of mouse rad9 causes abnormal cellular responses to DNA damage, genomic instability, and embryonic lethality

The fission yeast Schizosaccharomyces pombe rad9 gene promotes cell survival through activation of cell cycle checkpoints induced by DNA damage. Mouse embryonic stem cells with a targeted deletion of Mrad9, the mouse ortholog of this gene, were created to evaluate its function in mammals. Mrad9(-/-) cells demonstrated a marked increase in spontaneous chromosome aberrations and HPRT mutations, indicating a role in the maintenance of genomic integrity. These cells were also extremely sensitive to UV light, gamma rays, and hydroxyurea, and heterozygotes were somewhat sensitive to the last two agents relative to Mrad9(+/+) controls. Mrad9(-/-) cells could initiate but not maintain gamma-ray-induced G(2) delay and retained the ability to delay DNA synthesis rapidly after UV irradiation, suggesting that checkpoint abnormalities contribute little to the radiosensitivity observed. Ectopic expression of Mrad9 or human HRAD9 complemented Mrad9(-/-) cell defects, indicating that the gene has radioresponse and genomic maintenance functions that are evolutionarily conserved. Mrad9(+/-) mice were generated, but heterozygous intercrosses failed to yield Mrad9(-/-) pups, since embryos died at midgestation. Furthermore, Mrad9(-/-) mouse embryo fibroblasts were not viable. These investigations establish Mrad9 as a key mammalian genetic element of pathways that regulate the cellular response to DNA damage, maintenance of genomic integrity, and proper embryonic development.     

Radiation-induced chromosome aberrations in Saccharomyces cerevisiae: influence of DNA repair pathways.

Radiation-induced chromosome aberrations, particularly exchange-type aberrations, are thought to result from misrepair of DNA double-strand breaks. The relationship between individual pathways of break repair and aberration formation is not clear. By electrophoretic karyotyping of single-cell clones derived from irradiated cells, we have analyzed the induction of stable aberrations in haploid yeast cells mutated for the RAD52 gene, the RAD54 gene, the HDF1(= YKU70) gene, or combinations thereof. We found low and comparable frequencies of aberrational events in wildtype and hdf1 mutants, and assume that in these strains most of the survivors descended from cells that were in G2 phase during irradiation and therefore able to repair breaks by homologous recombination between sister chromatids. In the rad52 and the rad54 strains, enhanced formation of aberrations, mostly exchange-type aberrations, was detected, demonstrating the misrepair activity of a rejoining mechanism other than homologous recombination. No aberration was found in the rad52 hdf1 double mutant, and the frequency in the rad54 hdf1 mutant was very low. Hence, misrepair resulting in exchange-type aberrations depends largely on the presence of Hdf1, a component of the nonhomologous end-joining pathway in yeast.     

Manifestations of ageing at the cytogenetic level

The effects of ageing in humans appear to be a combination of influence of genetically programmed phenomena and exogenous environmental factors, and take place at the cellular level (senescence), rather than at the level of the organism. There are many processes, which occur in somatic cells as a consequence of DNA replication (accumulation of DNA errors or mutations that outstrip repair processes, telomere shortening, deregulation of apoptosis, etc.) and which drive replicative senescence in human cells. DNA errors are considered to be critical primary lesions in the formation of chromosomal aberrations. It can be concluded that the chromosome aberrations are biomarkers of ageing in human cells. Studies of human metaphases, interphase nuclei and micronuclei showed the increase in loss of chromosomes and the increase in frequency of stable chromosome aberrations as a function of age.     

Absence of DNA repair replication after chemical mutagen damage in Vicia faba

Exposure of human (Hela) cells to the mutagens 4-nitroquinoline-1-oxide (4NQO) and N-methyl-N′-nitro-nitrosoguanidine (MNNG) produces damage in DNA that is repaired by a mechanism involving the insertion of new bases into DNA (repair replication). Vicia faba root tips, either from soaked seeds containing non-proliferating cells or from growing roots, do not perform detectable amounts of repair replication even though the mutagens inhibit DNA synthesis and cause chromosome aberrations. In view of similar failures to resolve excision in Chlamydomonas, Haplopappus, and Nicotiana after irradiation with UV light and in Vicia faba after X-irradiation it appears that plants in general might lack this repair process.     

Induction by modified purines (2-aminopurine and 6-N-hydroxylaminopurine) of chromosome aberrations and aneuploidy in Syrian hamster embryo cells

The modified purines, 2-aminopurine and 6-N-hydroxylaminopurine, are known point mutagens in prokaryotic organisms. 2-Aminopurine is much less potent than 6-N-hydroxylaminopurine in inducing gene mutation in mammalian cells in culture and this corresponds to the relative activity of these two compounds in inducing tumors in rats and neoplastic transformation of Syrian hamster embryo cells in culture. We report here that these modified purines can induce chromosome aberrations, including chromatid gaps, breaks, and exchanges, as well as numerical chromosome changes in Syrian hamster embryo cells. These chromosome mutations occur over the concentration range of chemical needed to induced morphological transformation of the same cells. It is not known how nucleic base analogs induce chromosome mutations; however, this activity must be considered in attempting to understand the mechanism by which these agents induce neoplastic transformation of cells.     

Rapid Analysis of Chromosome Aberrations in Mouse B Lymphocytes by PNA-FISH

Defective DNA repair leads to increased genomic instability, which is the root cause of mutations that lead to tumorigenesis. Analysis of the frequency and type of chromosome aberrations in different cell types allows defects in DNA repair pathways to be elucidated. Understanding mammalian DNA repair biology has been greatly helped by the production of mice with knockouts in specific genes. The goal of this protocol is to quantify genomic instability in mouse B lymphocytes. Labeling of the telomeres using PNA-FISH probes (peptide nucleic acid - fluorescent in situ hybridization) facilitates the rapid analysis of genomic instability in metaphase chromosome spreads. B cells have specific advantages relative to fibroblasts, because they have normal ploidy and a higher mitotic index. Short-term culture of B cells therefore enables precise measurement of genomic instability in a primary cell population which is likely to have fewer secondary genetic mutations than what is typically found in transformed fibroblasts or patient cell lines.     

Transgenerational transmission of radiation induced genomic instability

Stability of genome is one of the evolutionary important trait of cells. Various mutations (gene, chromosomal, genomic) as well as artificial manipulations with genomes (inbreeding, DNA transfection, introduction of Br-DU in DNA) cause the genetic instability. Ionizing radiation is known as the factor which induced instability of genome in late mitotic descendants of cells after in vitro and in vivo exposure. Radiation induced genetic instability can be transmitted through germline cells. On the cell level both types of radiation induced genomic instability are manifested in elevated frequency of mutations, chromosome aberrations, micronuclei, increased radiosensitivity, disappearance of adaptive response, changes in gene expression. In studies of 1970-1980 years clear evidences on the different morphological and functional injuries in tissues of irradiated organisms as well as in tissues of the progeny of exposed parents were obtained. On the organism level the instability of mitotic and of meiotic progeny of irradiated cells is resulted in increased risk of cancer and of other somatic diseases. It seems to be useful to review the earlier radiobiology literature where delayed and transgenerational effects of ionizing radiation on tissues and on organisms level were clearly shown in animals. For the estimation of pathogenic role of radiation induced genomic instability in humans, particularly in children of exposed parents the parallel study of the same human cohorts using clinical parameters and various characteristic of genomic instability seems to be very important.     

Nucleotide sequence determination of point mutations at the mouse HPRT locus using in vitro amplification of HPRT mRNA sequences

Cloning of genomic and cDNA sequences of mammalian genes has made it possible to analyze at the molecular level mutations induced by radiation and chemical mutagens. The X-linked HPRT gene is very suitable for these investigations because in addition to the availability of cell culture systems, HPRT mutants can also be obtained directly from the lymphocytes of mouse and man. Recently a new technique has been introduced by Saiki and co-workers which allows the cloning and sequencing of small specific DNA segments from total genomic DNA after in vitro amplification of those segments up to 200,000-fold (Saiki et al., 1985). We have adapted this so-called polymerase chain reaction (PCR) procedure in such a way that the entire mouse HPRT-coding region could be amplified, cloned and sequenced. Instead of genomic DNA, we have used RNA as template in the PCR reactions. This allows us to detect point mutations in HPRT exon sequences in a very efficient way, since the DNA sequence of all 9 exons, which are scattered over 34 kb of DNA, can be obtained from only one amplification experiment. We studied the nature of 3 N-ethyl-N-nitrosourea (ENU)-induced HPRT mutants from cultured mouse lymphoma cells. One contains an A:T----G:C transition, the second an A:T----T:A transversion, whereas the third mutant is the result of abnormal splicing events, probably due to a mutation in the 3' splice site of the first intron.     

Natural Competence and the Evolution of DNA Uptake Specificity

Many bacteria are naturally competent, able to actively transport environmental DNA fragments across their cell envelope and into their cytoplasm. Because incoming DNA fragments can recombine with and replace homologous segments of the chromosome, competence provides cells with a potent mechanism of horizontal gene transfer as well as access to the nutrients in extracellular DNA. This review starts with an introductory overview of competence and continues with a detailed consideration of the DNA uptake specificity of competent proteobacteria in the Pasteurellaceae and Neisseriaceae. Species in these distantly related families exhibit strong preferences for genomic DNA from close relatives, a self-specificity arising from the combined effects of biases in the uptake machinery and genomic overrepresentation of the sequences this machinery prefers. Other competent species tested lack obvious uptake bias or uptake sequences, suggesting that strong convergent evolutionary forces have acted on these two families. Recent results show that uptake sequences have multiple “dialects,” with clades within each family preferring distinct sequence variants and having corresponding variants enriched in their genomes. Although the genomic consensus uptake sequences are 12 and 29 to 34 bp, uptake assays have found that only central cores of 3 to 4 bp, conserved across dialects, are crucial for uptake. The other bases, which differ between dialects, make weaker individual contributions but have important cooperative interactions. Together, these results make predictions about the mechanism of DNA uptake across the outer membrane, supporting a model for the evolutionary accumulation and stability of uptake sequences and suggesting that uptake biases may be more widespread than currently thought.     

Multicolour FISH in an analysis of chromosome aberrations induced by N-nitroso-N-methylurea and maleic hydrazide in barley cells

The present study is a rare example of a detailed characterization of chromosomal aberrations by identification of individual chromosomes (or chromosome arms) involved in their formation in plant cells by using fluorescent in situ hybridization (FISH). In addition, the first application of more than 2 DNA probes in FISH experiments in order to analyse chromosomal aberrations in plant cells is presented. Simultaneous FISH with 5S and 25S rDNA and, after reprobing of preparations, telomeric and centromeric DNA sequences as probes, were used to compare the cytogenetic effects of 2 chemical mutagens: N-nitroso-N-methylurea (MNU) and maleic hydrazide (MH) on root tip meristem cells of Hordeum vulgare (2n=14). The micronucleus (MN) test combined with FISH allowed the quantitative analysis of the involvement of specific chromosome fragments in micronuclei formation and thus enabled the possible origin of mutagen-induced micronuclei to be explained. Terminal deletions were most frequently caused by MH and MNU. The analysis of the frequency of micronuclei with signals of the investigated DNA probes showed differences between the frequency of MH- and MNU-induced micronuclei with specific signals. The micronuclei with 2 signals, telomeric DNA and rDNA (5S and/or 25S rDNA), were the most frequently observed in the case of both mutagens, but with a higher frequency after treatment with MH (46%) than MNU (37%). Also, 10% of MH-induced micronuclei were characterized by the presence of only telomere DNA sequences, whereas there were almost 3-fold more in the case of MNU-induced micronuclei (28%). Additionally, by using FISH with the same probes, an attempt was made to identify the origin of chromosome fragments in mitotic anaphase.     

Revision of th distribution of chromosome aberrations induced by chemical mutagens using the BUDR label

Cell distribution was analysed with the help of the BrDU label for the number of chromosome aberrations and breaks induced by one-center (thiophosphamide and phosphamide) and two-center (dipine and fotrine) mutagens at the stage G0 in the Ist mitosis of human lymphocytes harvested at different times of culturing (from 56 to 96 h). The comparison was made between the type of aberration distribution in cells and the dependence of their frequency on the harvesting point for various mutagens. Poisson aberration distribution in cells for two-center mutagens was found to correspond to their constant frequency observed at different times of harvesting. On the other hand, for one-center mutagens, a geometrical distribution of chromosome breaks corresponded to an exponential decrease in their frequency in time. It is suggested that two-center chemical mutagens and ionizing radiation cause largely short-live damages which are realized into chromosome aberrations rather quickly (during one cell cycle). One-center mutagens, however, cause such damages that the probability of their transformation into chromosome aberrations is decreasing rather slowly in time, under the exponential law, and their realization into chromosome aberrations can occur in subsequent cell cycle.     

Genetic Models in Applied Physiology. Functional genomics in the mouse: powerful techniques for unraveling the basis of human development and disease.

Now that near-complete DNA sequences of both the mouse and human genomes are available, the next major challenge will be to determine how each of these genes functions, both alone and in combination with other genes in the genome. The mouse has a long and rich history in biological research, and many consider it a model organism for the study of human development and disease. Over the past few years, exciting progress has been made in developing techniques for chromosome engineering, mutagenesis, mapping and maintenance of mutations, and identification of mutant genes in the mouse. In this mini-review, many of these powerful techniques will be presented along with their application to the study of development, physiology, and disease.     

DNA repair decline during mouse spermiogenesis results in the accumulation of heritable DNA damage

The postmeiotic phase of mouse spermatogenesis (spermiogenesis) is very sensitive to the genomic effects of environmental mutagens because as male germ cells form mature sperm they progressively lose the ability to repair DNA damage. We hypothesized that repeated exposures to mutagens during this repair-deficient phase result in the accumulation of heritable genomic damage in mouse sperm that leads to chromosomal aberrations in zygotes after fertilization. We used a combination of single or fractionated exposures to diepoxybutane (DEB), a component of tobacco smoke, to investigate how differential DNA repair efficiencies during the 3 weeks of spermiogenesis affected the accumulation of DEB-induced heritable damage in early spermatids (21-15 days before fertilization (dbf)), late spermatids (14-8dbf) and sperm (7-1dbf). Analysis of chromosomal aberrations in zygotic metaphases using PAINT/DAPI showed that late spermatids and sperm are unable to repair DEB-induced DNA damage as demonstrated by significant increases (P<0.001) in the frequencies of zygotes with chromosomal aberrations. Comparisons between single and fractionated exposures suggested that the DNA repair-deficient window during late spermiogenesis may be less than 2 weeks in the mouse and that during this repair-deficient window there is accumulation of DNA damage in sperm. Finally, the dose-response study in sperm indicated a linear response for both single and repeated exposures. These findings show that the differential DNA repair capacity of postmeiotic male germ cells has a major impact on the risk of paternally transmitted heritable damage and suggest that chronic exposures that may occur in the weeks prior to fertilization because of occupational or lifestyle factors (i.e., smoking) can lead to an accumulation of genetic damage in sperm and result in heritable chromosomal aberrations of paternal origin.