Chromosome damage induced by artificial seed aging in barley

Summary Barley (Hordeum vulgare L. Himalaya) seeds were artificially aged under two storage conditions (32 °C/12% moisture content (m.c.) and 38 °C/18% m.c.) to study the behavior of induced chromosomal aberrations during plant growth. The frequencies of aberrant anaphases at first mitosis in root tips were correlated with loss of germinability. However, after 3 and 5 weeks' growth, aberration frequency declined. In plants grown from artificially aged seeds, the frequency of aberrant anaphases appeared to be stabilized at about 1% after 5 weeks' growth, in spite of the large differences in the frequencies at first mitosis. This suggests that because of their genetic imbalance, cells with chromosomal aberrations induced by seed aging were being excluded during plant growth. Meiotic chromosome configurations at MI were normal (7 II) in all plants studied, although a few precocious separations were found. Meiotic aberrations were found at AI-TI, AII-TII and the tetrad stages in the pollen mother cells of plants grown from the control and artificially aged seeds. However, there were no clear differences among the control and the two aging treatments. It was obvious that some cells with meiotic chromosomal aberrations were lost between the AI-TI and AII-TII stages, and still more between the AII-TII and tetrad stages. The frequency of tetrads with micronuclei in plants produced from artificially aged seeds was the same as in the control. The plants grown from artificially aged seeds showed high pollen fertility (95.2 to 97.0%) and seed fertility (90.1 to 97.2%) which was comparable to the control values (97.4 and 97.9%) respectively, indicating no special effects of seed aging. Anaphase cells of the first mitosis in the next (A₂) generation were analyzed to study the transmission of chromosomal aberrations through mitotic and meiotic cell divisions in the A₁ generation. Aberrant anaphases in the progeny from the artificially aged seeds were not higher than those of the control progeny. This indicates that the chromosomal aberrations induced by seed aging are not transmitted to the next generation.Published with the approval of the Director of the Colorado state Experiment Station as Scientific Series No. 2776     

The breakage–fusion–bridge (BFB) cycle as a mechanism for generating genetic heterogeneity in osteosarcoma

Osteosarcoma (OS) is characterized by chromosomal instability and high copy number gene amplification. The breakage–fusion–bridge (BFB) cycle is a well-established mechanism of genome instability in tumors and in vitro models used to study the origins of complex chromosomal rearrangements and cancer genome amplification. To determine whether the BFB cycle could be increasing the de novo rate of formation of cytogenetic aberrations in OS, the frequency of anaphase bridge configurations and dicentric chromosomes in four OS cell lines was quantified. An increased level of anaphase bridges and dicentrics was observed in all the OS cell lines. There was also a strong association between the frequencies of anaphase bridges, dicentrics, centrosomal anomalies, and multipolar mitotic figures in all the OS cell lines, indicating a possible link in the mechanisms that led to the structural and numerical instabilities observed in OS. In summary, this study has provided strong support for the role of the BFB cycle in generating the extensive structural chromosome aberrations, as well as cell-to-cell cytogenetic variation observed in OS, thus conferring the genetic diversity for OS tumor progression.     

Number of aberrations per cell as a parameter of chromosome instability. 2. Comparative analysis of the factors of different nature

The average number of aberrations per aberrant cell was concluded to carry out information on chromosome instability peculiarities induced by different mutagens as it was shown in our previous work. The purpose of the current study was to present comparative analysis of intercellular distribution of number of aberrations and their theoretical approximations. Distribution of numbers of aberrations per cell in Allium cepa L. and Allium fistulosum L. root tip cells induced by different mutagenic factors (gamma-irradiation, thiotepa, formaldehyde and seed aging) have been studied. The results were approximated to theoretical Poisson, geometric and negative binomial distributions. The intercellular distribution of aberrations did not correspond to any of the used theoretical distributions when A. cepa seeds were gamma-irradiated. There was some, but not regular, accordance with theoretical distributions when chemical mutagens thiotepa in A. cepa and formaldehyde in A. fistulosum and seed aging in both species were evaluated. During seed aging frequency of aberrant cells increased more quickly in A. fistulosum in comparison with A. cepa.     

Genetic induction of chromosomal rearrangements in barley chromosome 7H added to common wheat

Chromosome 2C of Aegilops cylindrica induces chromosomal rearrangements in alien chromosome addition lines, as well as in euploid lines, of common wheat. To induce chromosomal rearrangements in barley chromosome 7H, reciprocal crosses were made between a mutation-inducing common wheat line that carries a pair of 7H chromosomes and one 2C chromosome and a 7H disomic addition line of common wheat. Many shrivelled seeds were included in the progeny, which was an indication of the occurrence of chromosome mutations. The chromosomal constitution of the viable progeny was examined by FISH (fluorescence in situ hybridization) using the barley subterminal repeat HvT01 as a probe. Structural changes of chromosome 7H were found in about 15% of the progeny of the reciprocal crosses. The aberrant 7H chromosomes were characterized by a combination of N-banding, FISH and genomic in situ hybridization. Mosaicism for aberrant 7H chromosomes was observed in seven plants. In total, 89 aberrant 7H chromosomes were identified in 82 plants, seven of which had double aberrations. More than half of the plants carried a simple deletion: four short-arm telosomes, one long-arm telosome, and 45 terminal deletions (23 in the short arm, 21 in the long arm, and one involving both arms). About 40% of the aberrations represented translocations between 7H and wheat chromosomes. Twenty of the translocations had wheat centromeres, 12 the 7H centromere, with translocation points in the 7HS (five) and in the 7HL (seven), and the remaining four were of Robertsonian type, three involving 7HS and one with 7HL. In addition, one translocation had a barley segment in an intercalary position of a wheat chromosome, and two were dicentric. The breakpoints of these aberrations were distributed along the entire length of chromosome 7H.     

9-beta-D-arabinofuranosyladenine increases the frequency of X-ray induced chromosome abnormalities in mammalian cells

Treatment of X-irradiated stationary Ehrlich ascites tumour cells with the DNA synthesis inhibitor beta-ara A (120 mumol/l, 30 min before and for 7 hours after irradiation) is shown to lead to a large increase in the incidence of anaphase chromosome abnormalities (anaphase bridges and fragments) at the first mitosis following irradiation. This increase is similar to the increase in cell killing observed for this cell line when treated with beta-ara A under the same conditions (Iliakis 1980). The results suggest that the increased frequency of chromosome abnormalities caused by beta-ara A may result not only from the inhibition of DNA double strand break repair, leading to additional unrepaired d.s.b. (Bryant and Bl?cher 1982) and chromosome deletions, but also from an increase in the frequency of misrepair of d.s.b. leading to exchange aberrations.     

Cytogenetic analysis of alloplasmic recombinant lines (H. vulgare)-T. aestivum with unstable fertility and viability

Comparative cytogenetic analysis was performed with four alloplasmic recombinant (Hordeum vulgare)-Triticum aestivum lines differing in morphological traits, number of seeds per spike, and seed plumpness. None of the lines displayed introgression of the barley genetic material: the karyotypes included only common wheat chromosomes. Two lines, 79(B) and 79(D), were cytogenetically stable. Plants of lines 79(A) and 79(C) displayed a high frequency of unbalanced chromosome aberrations, including dicentric and polycentric chromosomes, terminal deletions varying in size, acentric fragments, and multiple unidentifiable translocations. Previous studies of the mitochondrial genome showed that the two cytologically unstable lines, which were also unstable in fertility and viability, are characterized by heteroplasmy at the mitochondrial 18S-5S locus (simultaneous presence of barley and wheat fragments). Stable lines 79(B) and 79(D) with normal fertility contained only wheat mitochondrial markers. It was assumed that the substantial instability of the nuclear genome in lines 79(C) and 79(A) was a result of nuclear-cytoplasmic incompatibility and was associated with heteroplasmy, while elimination or considerable reduction of barley material in the mitochondrial genome stabilized the nuclear genome of lines 79(B) and 79(D). In turn, the instability of the nuclear genome was responsible for a decrease in viability and fertility of plants.     

Dynamics of chromosomal instability in Welsh onion (Allium fistulosum L.): Influence of seed storage temperature

The age-related dynamics of chromosomal instability in cells of the root meristem of seedlings and germination capacity of seeds of Welsh onion (Allium fistulosum L.) in two storage temperature regimes in the course of six years following collection of the seeds are investigated. Seeds that had been stored at room temperature (14–28°C) lost germination capacity after six years of storage. The frequency of aberrant anaphases in these seeds grew from 2% in the first month of storage of the seeds to 80% in the 75th month. The germination capacity of seeds that had been stored at reduced temperatures (4–9°C) amounted to 73–77% in the sixth year, while the frequency of aberrant anaphases in these seeds remained within the range 2–4% throughout the six years. Thus, storage of Welsh onion seeds for six years at reduced temperatures tends to preserve the germination capacity of the seeds and prevents the development of chromosomal instability in the root meristem cells of the seedlings over this period.     

The usage of the index “frequency of chromosomal aberrations” for the risk group formation in respect to oncologic diseases

It has been well established that chromosome instability involves the effect of environmental mutagenic factors. In addition, chromosomal aberrations can be markers of gene changes such as in oncology. So far, there is no unequivocal explanation of age relatedness for the frequency of chromosomal aberrations in the examined individuals or the increased level of this index in oncologic patients. Therefore, the value of the index “frequency of chromosomal aberrations” can be used to form the risk groups, including oncologic, for more profound studies using other methods.     

PCR and sequence analysis of barley chromosome 2H subjected to the gametocidal action of chromosome 2C

Gametocidal (Gc) chromosomes induce various types of chromosomal mutations during gametogenesis in the chromosomes of common wheat and alien chromosomes added to common wheat. However, it is not yet known whether the Gc chromosome causes aberrations at the nucleotide level because mutations caused by Gc chromosomes have been studied only by cytological screening. In order to know whether the Gc chromosome induces point mutations, we conducted PCR analysis and sequencing with the progeny of a common wheat line that is disomic for barley chromosome 2H and monosomic for Gc chromosome 2C. We analyzed 18 2H-specific EST sequences using 81 progeny plants carrying a cytologically normal-appearing 2H chromosome and found no nucleotide changes in the analyzed 1,419 sequences (in total 647,075 bp). During this analysis, we found six plants for which some ESTs could not be PCR amplified, suggesting the presence of chromosomal mutations in these plants. The cytological and PCR analyses of the progeny of the six plants confirmed the occurrence of chromosomal mutations in the parental plants. These results suggested that the Gc chromosome mostly induced chromosomal aberrations, not nucleotide changes, and that the Gc-induced chromosomal mutations in the six plants occurred after fertilization.     

Inverted DNA repeats channel repair of distant double-strand breaks into chromatid fusions and chromosomal rearrangements

Inverted DNA repeats are known to cause genomic instabilities. Here we demonstrate that double-strand DNA breaks (DSBs) introduced a large distance from inverted repeats in the yeast (Saccharomyces cerevisiae) chromosome lead to a burst of genomic instability. Inverted repeats located as far as 21 kb from each other caused chromosome rearrangements in response to a single DSB. We demonstrate that the DSB initiates a pairing interaction between inverted repeats, resulting in the formation of large dicentric inverted dimers. Furthermore, we observed that propagation of cells containing inverted dimers led to gross chromosomal rearrangements, including translocations, truncations, and amplifications. Finally, our data suggest that break-induced replication is responsible for the formation of translocations resulting from anaphase breakage of inverted dimers. We propose a model explaining the formation of inverted dicentric dimers by intermolecular single-strand annealing (SSA) between inverted DNA repeats. According to this model, anaphase breakage of inverted dicentric dimers leads to gross chromosomal rearrangements (GCR). This "SSA-GCR" pathway is likely to be important in the repair of isochromatid breaks resulting from collapsed replication forks, certain types of radiation, or telomere aberrations that mimic isochromatid breaks.     

Über das Verhalten eines Ringchromosoms in der Mitose und Meiose von Antirrhinum majus L.

Summary The mitotic and meiotic behaviour of a ring-chromosome in Antirrhinum majus was analysed. 26.5% mitotic anaphases showed bridges demonstrating the occurrence of a crossing-over-like process in meristematic cells. From pachytene studies the ring-chromosome could be identified as chromosome 6.An attempt was made to derive the details of the crossing-over process from the various anaphase configurations in pollen mother cells with a heterozygous ring-rod-bivalent. The observed frequencies could only be brought in approximate correspondance with theoretical values by postulating (i) the occurrence of sister-strand and non-sister-strand crossing-over in certain quantitative combinations, and (ii) an unexplained loss or irricognizability of most double bridges in anaphase I.The frequency of plants heterozygous for the ring-chromosome in progenies after seifing was 16.8%. The rate of chromosome mutations in these progenies was not increased. Chromosomal aberrations resulting from meiotic disturbances in the ring plants are probably lost by gonal elimination of unbalanced chromosome sets.     

Chromosome instabilities and programmed cell death in tapetal cells of maize with B chromosomes and effects on pollen viability

B chromosomes (B's), knobbed chromosomes, and chromosome 6 (NOR) of maize undergo nondisjunction and micronucleus formation in binucleate tapetal cells. These chromosome instabilities are regular events in the program of tapetal cell death, but the B's strongly increase A chromosome instability. We studied 1B and 0B plants belonging to selected lines for high or low B transmission rate and their F1 hybrids. These lines are characterized by meiotic conservation or loss of B chromosomes, respectively. The female B transmission (fBtl) allele(s) for low B transmission is dominant, inducing micronucleus formation and B nondisjunction. We hypothesize that the fBtl allele(s) induces knob instability. This instability would be sufficient to produce B loss in both meiocytes and binucleate tapetal cells. B instability could, in turn, produce instabilities in all chromosomes of maize complement. To establish whether the chromosomal instabilities are related to the tapetal programmed cell death (PCD) process, we applied the TUNEL technique. PCD, estimated as the frequency of binucleate tapetal cells with TUNEL label, was significantly correlated with the formation of micronuclei and the frequency of pollen abortion. It can be concluded that the observed chromosome instabilities are important to the PCD process and to the development of microspores to form viable pollen grains.     

Role of some growth regulators on cytogenetic activity of barley under salt stress

The effects of gibberellic acid (GA₃), kinetin (KIN), benzyladenine and ethylene (E) on mitotic activity and chromosomal aberrations in root tips of barley seeds (Hordeum vulgare L. cv. “Bülbül 89”) germinated under salt stress were investigated. It was determined that all of these plant growth regulators (PGRs) decreased mitotic index in root tips of barley seeds germinated at 20 °C and in distilled water. Furthermore, some of the PGRs studied increased significantly the frequency of chromosomal aberrations. The frequency of chromosomal aberrations in seeds treated with E and KIN was considerably higher than in the seeds germinated under nonstress conditions. The inhibitory effect of salt stress on mitotic index increased with increasing salt concentration (0.30, 0.35, 0.40 and 0.45 molal, m). GA₃ and KIN pretreatments showed a successful performance in ameliorating the negative effects of increasing salinity on mitotic activity. The number of chromosomal aberrations also increased with increasing NaCl concentration. However, most of the PGR pretreatments studied alleviated the detrimental effects of increasing salinity on chromosomal aberrations. KIN pretreatment at 0.30 and 0.35 m salinity could not rescued the cytogenetic activity of salt stress on this parameter.     

Anti-clastogenic ingredients in Cassia nomame extract

The suppressing effect of the hot-water extract of Cassia nomame (Sieb.) HONDA was studied on the frequency of chromosomal aberrations in Chinese hamster ovary K1 (CHO-K1) cells. CHO-K1 cells were pretreated with 2.5 microM Mitomycin C (MMC) for 1 h and incubated with or without the extract in medium for 10-24 h. The frequency of chromosome aberrations in observed 100 metaphase cells was significantly lower with the extract than that without the extract. Moreover, the suppressing effect of the four fractions collected by high performance liquid chromatography (HPLC) was also examined on the same procedure. The frequency of cells with chromosome aberrations in cells cultured with each collected fraction was lower than in those without the extract. The suppressing effect of the collected fractions on chromosomal aberrations, however, was less than that of the total extract. This result suggests that the ingredients which have the suppressing effect of chromosomal aberrations are also contained in the other fraction of the extract.     

Cytogenetic analysis of alloplasmic recombinant lines (H. vulgare)—T. aestivum unstable in fertility and viability

Comparative cytogenetic analysis was performed with four alloplasmic recombinant (Hordeum vulgare)—Triticum aestivum lines differing in morphological traits, number of seeds per spike, and seed plumpness. None of the lines displayed introgression of the barley genetic material: the karyotypes included only common wheat chromosomes. Two lines, 79(B) and 79(D), were cytogenetically stable. Plants of lines 79(A) and 79(C) displayed a high frequency of unbalanced chromosome aberrations, including dicentric and polycentric chromosomes, terminal deletions varying in size, acentric fragments, and multiple unidentifiable translocations. Previous studies of the mitochondrial (mt) genome showed that the two cytologically unstable lines 79(C) and 79(A), which were also unstable in fertility and viability, are characterized by heteroplasmy at the mitochondrial 18S-5S locus (simultaneous presence of barley and wheat mt-fragments). Stable lines 79(B) and 79(D) with normal fertility contained only wheat mitochondrial markers. It was assumed that the substantial instability of the nuclear genome in lines 79(C) and 79(A) was a result of nuclear-cytoplasmic incompatibility and was associated with heteroplasmy, while elimination or considerable reduction of barley material in the mitochondrial genome stabilized the nuclear genome of lines 79(B) and 79(D). In turn, the instability of the nuclear genome was responsible for a decrease in viability and fertility of plants.     

Repair of single-strand DNA breaks and recovery of chromosomal and chromatid aberrations after treatment of plant seeds with propyl methanesulfonate in vivo.

Repair of single-strand breaks of DNA and simultaneous recovery of chromosomal aberrations were studied after treatment of barley seeds with the monofunctional alkylating chemical mutagen, propyl methanesulfonate in vivo. In soaked seeds the diminution of single-strand breaks of DNA induced by PMS was correlated with the decrease of chromosomal aberrations, whereas in dried seeds the repair of DNA breaks was depressed and, in accord with this, the frequency of chromosomal aberrations increased. The prolonged storage of seeds led to a more delayed repair of chromosomal aberrations in dry seeds and a more delayed accelerated repair in soaked seeds.     

Acceleration of chromosome aberrations in senescence-accelerated strains of mice

Age-related changes in the frequency of chromosome aberrations were examined using bone marrow cells of senescence-accelerated strains of mice (SAM). An accelerated senescence-prone strain, SAM-P/1, showed a striking increase in the frequency of chromosome aberrations, from age 3 to 8 months, whereas an accelerated senescence-resistant strain, SAM-R/1, at the same ages showed only a slight increase. Both these strains were derived from the same ancestral strain (AKR/J). The rate of increase of chromosome aberration frequency paralleled the advancement of senescence in both strains. These observations suggest that there are genetic factors which closely relate to chromosomal instability and acceleration of the senescence processes.     

Meiotic chromosomal variation resulting from irradiation of pollen in maize

The objective of this study was to standardize an induction strategy of chromosome aberrations in maize inbred line L-869. Pollen grains irradiated with 0, 36 and 72 Gy were used for fertilization. Resulting seeds were planted in a greenhouse to assess the number of abnormal meiotic cells. Germination, height, sterility and mortality were verified. Cells with delayed separation of chromosomes, translocation, deficiency, abnormal pairing, later condensation and anaphase bridges were observed. The number of abnormalities increased as the dosage increased but chromosome aberration types were the same regardless of the dosages used. Various chromosome-altered plants were obtained without viability loss     

A new FISH assay to simultaneously detect structural and numerical chromosomal abnormalities in mouse sperm

De novo aberrations in chromosome structure represent important categories of paternally transmitted genetic damage. Unlike numerical abnormalities, the majority of de novo structural aberrations among human offspring are of paternal origin. We report the development of a three-color fluorescence in situ hybridization (FISH) assay (CT8) to detect mouse sperm carrying structural and numerical chromosomal abnormalities. The CT8 assay uses DNA probes for the centromeric and telomeric regions of chromosome 2, and a probe for the subcentromeric region of chromosome 8. The CT8 assay was used to measure the frequencies of sperm carrying certain structural aberrations involving chromosome 2 (del2ter, dup2ter, del2cen, dup2cen), disomy 2, disomy 8, and sperm diploidy. Analysis of approximately 80,000 sperm from eight B6C3F1 mice revealed an average baseline frequency of 2.5 per 10,000 sperm carrying partial duplications and deletions of chromosome 2. Extrapolated to the entire haploid genome, approximately 0.4% of mouse sperm are estimated to carry structural chromosomal aberrations, which is more than fivefold lower than the spontaneous frequencies of sperm with chromosome structural aberrations in man. We validated the CT8 assay by comparing the frequencies of abnormal segregants in sperm of T(2;14) translocation carriers detected by this assay against those detected by chromosome painting cytogenetic analysis of meiosis II spermatocytes. The CT8 sperm FISH assay is a promising method for detecting structural chromosome aberrations in mouse sperm with widespread applications in genetics, physiology, and genetic toxicology.     

Chromosomal instability in the lymphocytes of breast cancer patients

Genomic instability in the tumor tissue has been correlated with tumor progression. In the present study, chromosomal aberrations (CAs) in peripheral blood lymphocytes (PBLs) of breast tumor patients were studied to assess whether chromosomal instability (CIN) in PBLs correlates with aggressiveness of breast tumor (i.e., disease stage) and has any prognostic utility. Cultured blood lymphocyte metaphases were scored for aberrations in 31 breast cancer patients and 20 healthy age and sex-matched controls. A variety of CAs, including aneuploidy, polyploidy, terminal deletions, acentric fragments, double minutes, chromatid separations, ring chromosome, marker chromosome, chromatid gaps, and breaks were seen in PBLs of the patients. The CAs in patients were higher than in controls. A comparison of the frequency of metaphases with aberrations by grouping the patients according to the stage of advancement of disease did not reveal any consistent pattern of variation in lymphocytic CIN. Neither was any specific chromosomal abnormality found to be associated with the stage of cancer. This might be indicative of the fact that cancer patients have constitutional CIN, which predisposes them to the disease, and this inherent difference in the level of genomic instability might play a role in disease progression and response to treatment.