A genetic assay for the detection of aneuploidy in the germ-line cells of Drosophila melanogaster

A 2-generation assay is described for the detection of aneuploidy in the germ-line cells of Drosophila melanogaster. Larvae and adult females that carry marker mutations are exposed to test compounds, and the F2 generation is scored for exceptional phenotypes. As a consequence of nondisjunction and/or loss of the sex chromosomes, 5 exceptional phenotypes appear. These phenotypes are often indicative of specific types of nondisjunction. Based on the time course and the pattern of exception production of the treated parents, aneuploidy due to meiotic and mitotic defects can be separated. The genetic analysis of the exceptions reveals whether nondisjunction has occurred due to failure of the spindle fibres to disjoin chromosomes or attachment of the chromosomes. The described assay is an extension of the so-called Somatic Mutation and Recombination Test (SMART) and allows screening for different genetic endpoints: aneuploidy, recombinogenic and mutagenic activities in the same treatment. The effects of colchicine and EMS are described with respect to the induction of aneuploidy in the germ line and somatic mutation and recombination in the eyes, wings and female germ-line cells. Colchicine induces aneuploidy in the germ-line cells while the frequency of mosaic spots does not increase after colchicine treatment. This result suggests that aneuploidy plays little (if any) role in the formation of mosaic spots. Colchicine induces nondisjunction in the mitotically rather than in the meiotically dividing germ-line cells. EMS, as expected, induces high frequency of somatic mutation and recombination but not aneuploidy in the female germ line.     

Genotoxicity of Rogor studied in the sex-linked recessive lethal test and wing, eye and female germ-line mosaic assays in Drosophila melanogaster

The genotoxic potential of Rogor (dimethoate), an anticholinesterase organophosphate insecticide, has been studied in the sex-linked recessive lethal test and the wing, eye and female germ-line mosaic assays in Drosophila melanogaster. Larvae of different instars carrying suitable recessive genetic markers on their first and third chromosomes were exposed to the LD50 or half of this dose for the entire larval life. The Basc technique was followed for the detection of the induction of sex-linked recessive lethals. The wings and eyes of the adult flies and the eggs laid by the heterozygous females were checked for the induction of mosaicism. It is concluded that Rogor induces sex-linked recessive lethals in immature male germ cells and is recombinogenic and/or mutagenic in both the somatic and the germ-line cells of Drosophila.     

Genotoxicity of zineb detected through the somatic and germ-line mosaic assays and the sex-linked recessive-lethal test in Drosophila melanogaster

The genotoxicity of zineb, a carbamate fungicide, has been tested through eye, wing and female germ line mosaic assays and the sex-linked recessive-lethal test in Drosophila melanogaster. Larvae of different instars, heterozygous for appropriate recessive genetic markers, were exposed to the fungicide in food for different durations of time. The adult eyes and wings were screened for induction of mosaic spots and the eggs laid by the females were checked for induction of female germ-line mosaicism. It is concluded that zineb is genotoxic to both somatic and germ-line cells of Drosophila.     

Genotoxicity of ziram established through wing, eye and female germ-line mosaic assays and the sex-linked recessive lethal test in Drosophila melanogaster

The genotoxicity of ziram (zinc-dimethyl dithiocarbamate, CAS No. 137-30-4), a carbamate fungicide, is studied in the wing, eye and female germ-line mosaic assays and the sex-linked recessive lethal test in Drosophila melanogaster. First-, second- and third-instar larvae, carrying suitable recessive genetic markers on their first and third chromosomes, were exposed to ziram. Wings and eyes of adults were screened for the induction of mosaic spots and the eggs laid by adult females for germ-line mosaicism. The Basc method was used to detect sex-linked recessive lethals. Ziram is genotoxic to the somatic and germ cells of Drosophila melanogaster.     

The Absence of Somatic Effects of P-M Hybrid Dysgenesis in DROSOPHILA MELANOGASTER

The wings and abdomens of dysgenic and nondysgenic control flies were scored for the presence of clones of cells mutant for first and third chromosome markers. These exceptional clones can arise from mitotic recombination, de novo mutation or deletion, and P-M hybrid dysgenesis has been shown to increase the frequency of parallel processes occurring in germ-line cells. Particular attention was given to careful genetic and molecular characterization of all stocks and to providing adequate and appropriate controls so that even very small increases in somatic clone frequency due to P-M hybrid dysgenesis would be detected. No difference was found in the frequency, size distribution or anatomical distribution of mutant somatic clones correlated to hybrid dysgenesis, confirming previous indications. The potential adaptive significance of a germ-line restriction of P-M hybrid dysgenesis is discussed.     

Elevated Micronucleus Frequency in Bone Marrow Erythrocytes in the Progeny of Male Mice Exposed to Chronic Low-Dose Gamma Irradiation

The micronucleus frequency in bone marrow erythrocytes from the F1 progeny of male mice exposed to chronic low-dose -irradiation was determined. Male BALB/c mice were irradiated with 10, 25 and 50 cGy at dose rates of 1, 5, and 15 cGy/day and mated with unirradiated females on day 15 after irradiation. The obtained offspring had an elevated micronucleus frequency in bone marrow erythrocytes at the age of 2 months. This suggests the transmission of genome instability from damaged germ-line cells of irradiated male parents to somatic cells of the progeny.     

Genetic efficacy of low doses of ionizing radiation in chronically-irradiated small mammals

Earlier we have established the genetic effects of low dose chronic irradiation in bank vole (somatic and germ cells, embryos), in pond carp (fertilized eggs, embryos, fry) and in laboratory mice (somatic and germ cells) in the range of doses from near-background to 10 cGy. These low dose effects observed in mammals and fish are not expected from extrapolation of high dose experiments. For understanding reasons this discrepancy the comparative analysis of genetic efficiency of low dose chronic irradiation and the higher doses of acute irradiation was carried out with natural populations of bank vole which inhabited the two sites differing in ground of radionuclide deposition. For comparing efficiency the linear regression model of dose-effect curve was used. Dose-effect equations were obtained for animals from two chronically irradiated bank vole populations. The mean population absorbed doses were in the range 0.04-0.68 cGy, the main part of absorbed doses consisted of external radiation of animals exposed to 137Cs gamma-rays. Dose-effect equations for acute irradiation to 137Cs gamma-rays (10-100 cGy) were determined for the same populations. Comparison of genetic efficiency was made by extrapolation, using regression coefficient beta and doubling dose estimation. For chronic exposure the doubling doses calculated from low-dose experiments are 0.1-2 cGy and the doubling doses determined from high-dose experiments are in the range of 5-20 cGy. Our hypothesis that the doubling dose estimate is calculated in higher-dose ionizing radiation experiments should be much higher than the deduced from the low dose line regression equation was verified. The doubling dose estimates for somatic cells of bank vole and those for germ cells of laboratory mice are in close agreement. The radiosensitivity of bank vole chromosomes were shown is practically the same as that for human lymphocytes since doubling dose estimates for acute irradiation close to each other. For low LET radiation a higher genetic efficiency of chronic low doses in comparison with the higher doses of acute gamma-irradiation (137Cs source) was proved by three methods.     

Recurrence of lethal osteogenesis imperfecta due to parental mosaicism for a dominant mutation in a human type I collagen gene (COL1A1).

We have determined that two infants with perinatal lethal osteogenesis imperfecta in one family had the same new dominant point mutation. Although not detected in his dermal fibroblast DNA, the mutation was detected in somatic DNA from the father's hair root bulbs and lymphocytes. The mutation was also detected in the father's sperm, demonstrating that mosaicism in the father's germ line explains recurrence. The presence of both germ-line and somatic mosaicism indicates that the mutation occurred prior to segregation of the germ-line and somatic cell progenitors. About one in eight sperm carry the mutation, which implies that at least four progenitor cells populate the germ line in human males. The observation that the mosaic individual is clinically normal suggests that genetic diseases can have both qualitative and quantitative components.     

Transgenerational carcinogenesis: induction and transmission of genetic alterations and mechanisms of carcinogenesis

Parental exposure, i.e. germ cell exposure to radiation and chemicals, increased the incidence of tumors and malformations in the offspring, and the germ-line alterations that cause cancer are transmissible to further generations. However, tumor incidences were 100-fold higher than those of ordinary mouse mutations and there were apparent strain differences in the types of induced tumors. In human, higher risk of leukemia is reported in the children of fathers who had been exposed to radionuclides at the nuclear reprocessing plants or to diagnostic doses of radiation. However, these findings in mice and men have not been confirmed in the children of atomic bomb survivors in Hiroshima and Nagasaki. Another important finding was that germ-line exposure was very weakly tumorigenic by itself. However, the transmissible alterations caused persistent hypersensitivity to tumor induction in the offspring, e.g. enhanced by postnatal treatment with tumor promoting/carcinogenic agents. The above results suggest that transmissible alterations might be imprinted in germ cells for the future development of cancer by the postnatal environment. Many gene loci concerning immunological, biochemical and physiological function might be involved, and the cumulative changes in such genes may slightly elevate or enhance tumor incidences, although mutations of tumor suppressor genes such as p53 were also detected in some offspring and genomic instability may modify tumor occurrence in transgenerational manner. In fact, Gene Chip analysis showed suppression and/or over-expression of many functional genes rather than cancer-related genes in the preconceptionally irradiated cancer prone progeny.     

Analysis of the Behavior of Mitochondria in the Ovaries of the Earthworm Dendrobaena veneta Rosa 1839

We examined six types of cells that form the ovary of the earthworm Dendrobena veneta ogonia, prooocytes, vitellogenic oocytes, trophocytes, fully grown postvitellogenic oocytes and somatic cells of the gonad. The quantitative stereological method revealed a much higher “volume density” of mitochondria in all of the types of germ-line cells except for the somatic cells. Fluorescent vital stain JC-1, however, showed a much higher oxidative activity of mitochondria in the somatic cells than in the germ-line cells. The distribution of active and inactive mitochondria within the studied cells was assessed using the computer program ImageJ. The analysis showed a higher luminosity of inactive mitochondria in all of the types of germ-line cells and a higher luminosity of active mitochondria in somatic cells. The OXPHOS activity was found in somatic cells mitochondria and in the peripheral mitochondria of the vitellogenic oocytes. The detection of reactive oxygen species (ROS) revealed a differentiated distribution of ROS in the different cell types. The amount of ROS substances was lower in somatic cells than in younger germ-line cells. The ROS level was also low in the cytoplasm of fully grown postwitellogenic oocytes. The distribution of the MnSOD enzyme that protects mitochondria against destructive role of ROS substances was high in the oogonia and in prooocytes and it was very high in vitellogenic and postvitellogenic oocytes. However, a much lower level of this protective enzyme was observed in the trophocytes and the lowest level was found in the cytoplasm of somatic cells. The lower mitochondrial activity and higher level of MnSOD activity in germ-line cells when compared to somatic cells testifies to the necessity of the organisms to protect the mitochondria of oocytes against the destructive role of the ROS that are produced during oxidative phosphorylation. The protection of the mitochondria in oocytes is essential for the transfer of healthy organelles to the next generation.     

Contributions to somatic and germline lineages of chicken blastodermal cells maintained in culture

Chicken blastodermal cells were cultured for 48 hr as explanted intact embryos, as dispersed cells in a monolayer, or with a confluent layer of mouse fibroblasts. The cells were then dispersed and injected into stage X (E-G&K) recipient embryos that were exposed to 600 rads of irradiation from a ⁶⁰Co source. Regardless of the conditions in which the cells were cultured, chimeras with contributions to both somatic tissues and the germline were observed. When blastodermal cells were co-cultured with mouse embryonic fibroblasts, significantly more somatic chimeras were observed and the proportion of feather follicles derived from donor cells was increased relative to that observed following the injection of cells derived from explanted embryos or monolayer cultures. Culture of blastodermal cells in any of the systems, however, yielded fewer chimeras that exhibited reduced contributions to somatic tissues in comparison to the frequency and extent of somatic chimerism observed following injection of freshly prepared cells. Contributions to the germline were observed at an equal frequency regardless of the conditions of culture, but were significantly reduced in comparison to the frequency and rate of germ-line transmission following injection of cells obtained directly from stage X (E-G&K) embryos. These data demonstrate that some cells retain the ability to contribute to germline and somatic tissues after 48 hr in culture and that the ability to contribute to the somatic and germline lineages is not retained equally. © 1996 Wiley-Liss, Inc.     

Autoimmune mice and stimulated normal mice make lambda 1 with increased V region diversity

Previous studies of the genetic bases of murine SLE have defined gene segments that encode the H chain and the kappa L chain of anti-DNA, anti-Sm, and anti-IgG autoantibodies. As a result of these studies, the genetic origins of autoantibody H chains and kappa L chains are better understood, but little remains known about the genetic bases of autoantibody lambda-chains. Thus, we have analyzed serologically the germ-line and somatic origins of lambda 1 L chains in antibodies of normal mice and in both antibodies and autoantibodies of autoimmune mice. This study finds an increased lambda 1 diversity in both Ag-stimulated mice and autoimmune mice. This study also finds that the lambda 1 L chains in antibodies of unstimulated normal mice have the gene segment-encoded variable region, V lambda 1. In contrast, additional genetic processes appear to make the lambda 1 V regions of antibodies in Ag-stimulated normal mice and the lambda 1 V regions of both antibodies and autoantibodies in autoimmune mice. The increased lambda 1 diversity that we found in both Ag-stimulated mice and autoimmune mice might be caused by mutational processes creating antibody diversities. Therefore, the same somatic processes might be able to make both antibody and autoantibody lambda 1 diversities.     

Germ line mosaicism

Mosaicism in germ cells has been recognized, over the past few years, as an important and relatively frequent mechanism at the origin of genetic disorders. There are two possibilities for the existence of such a mosaicism: one is that the mutation occurs in a germ cell that continues to divide. The other possibility is that the mutation occurs very early in a somatic cell before the separation to germinal cells and is therefore present both in somatic and germinal cells. Depending on various factors, such as the gene involved and/or the degree of mosaicism, the carrier of a somatic and germline mosaicism may be asymptomatic or may present with various symptoms of the disease. There are still relatively few reports in the literature in which the origin of germ-line mosaicism has been analyzed; nevertheless, they allow for a better insight into the mechanisms involved. In some diseases, such as osteogenesis imperfecta, new mutations are often present as asymptomatic somatic and germline mosaicism in one of the parents of the propositus. In other disorders, such as neurofibromatosis, somatic mosaicism is very rare in the parents of the propositus, perhaps since such mosaicism causes clinical symptoms. These differences are particularly important for genetic counseling in order to evaluate the risk for another affected child after the birth of the propositus. Received: 15 September 1997 / Accepted: 12 January 1998     

The initiation of senescence and its relationship to embryonic cell differentiation

Mouse embryonic stem cells have an unlimited lifespan in cultures if they are prevented from differentiating. After differentiating, they produce cells which divide only a limited number of times. These changes seen in cultures parallel events that occur in the developing embryo, where immortal embryonic cells differentiate and produce mortal somatic ones. The data strongly suggest that differentiation initiates senescence, but this view entails additional assumptions in order to explain how the highly differentiated sexual gametes manage to remain potentially immortal. Cells differentiate by blocking expression from large parts of their genome and it is suggested that losses or gains of genetic totipotency determine cellular lifespans. Cells destined to be somatic do not regain totipotency and senesce, while germ-line cells regain complete genome expression and immortality after meiosis and gamete fusions. Losses of genetic totipotency could induce senescence by lowering the levels of repair and maintenance enzymes.     

The comparative analysis of gene and structural somatic mutations in inhabitants of Orel district areas contaminated with radionuclides as a result of Chernobyl accident

The results of comparative analysis of gene and structural mutations found in peripheral blood lymphocytes of inhabitants of Orel district areas contaminated with radionuclides as a result of Chernobyl accident are presented. The average level of 137Cs contamination in those areas ranged about 22-113 kBq/m2. In the study group was found the enhanced frequency of somatic cells with gene and structural mutations compared with laboratory control level by synchronous applying a T-cell receptor (TCR) loci mutation assay and cytogenetic analysis of unstable aberrations. The case-control comparison was carried out using the measured mutation frequencies and cases of various thyroid gland sickness recognized by ultrasonic examination. The cytogenetic assay did not show the statistical difference between healthy group and subjects with thyroid gland sickness. The average frequency of TCR loci mutation cells in the subjects with thyroid gland sickness was found to be statistically higher comparing with healthy persons. This finding was true for each study region and for Orel district in total. The subgroup of subject exposed in utero in 1986, soon after accident was analyzed. Both cytogenetic and TCR loci mutation assays shown enhancement of average mutation frequency in somatic cells in the subjects of this subgroup with thyroid gland sickness comparing with healthy persons.     

Germ line polysomy in the grasshopper Atractomorpha similis

Nineteen Eastern Australian populations of the grasshopper Atractomorpha similis (Acridoidea, Pyrgomorphidae) were sampled and male meiotic chromosomes, as well as some male and female somatic mitoses, were examined. In fourteen of these populations, a proportion of the males were found to carry between one and ten extra copies of a particular autosome, the megameric chromosome (A9). Numbers of extra chromosomes varied between but not within the individual follicles of the testis. The extra chromosomes were not found in somatic tissue. In all, 20% of males from the field were germ-line polysomic and within these males, 91% of germ cells were polysomic. In meiosis, extra copies of A9 present as univalents lagged at anaphase I or II and subsequently formed micronuclei which degenerated early in spermiogenesis. As one extra univalent is the most common polysomic condition in natural populations, this elimination of univalents suggests that most polysomic males produce a large proportion of normal haploid sperm. In laboratory cultures, selection for increased frequency of germ-line polysomy, conducted over four generations, raised the proportion of polysomic males from 23% to 71%. Selection against polysomy reduced its frequency to 5%. These breeding experiments also showed that germ-line polysomy is equally transmissible through both the male and the female parent. Transmission data also suggested that these extra chromosomes can arise de novo, presumably by unequal disjunction in previously diploid lines. A computer model was devised, simulating the effects of repeated non-disjunction over a series of mitotic divisions. The behaviour of this model suggested that the distributions of extra chromosome numbers observed in the laboratory generations most probably resulted from such a series of non-disjunctions, occurring in an initially diploid cell population. It seems, therefore, that the transmission of polysomy occurs through the agency of heritable factors which determine the probability of non-disjunction and thus the accumulation of a particular autosome during a specific series of mitotic divisions in the embryonic germ-line.     

Post-integration behavior of a Mos1 mariner gene vector in Aedes aegypti

The post-integration behavior of insect gene vectors will determine the types of applications for which they can be used. Transposon mutagenesis, enhancer trapping, and the use of transposable elements as genetic drive systems in insects requires transposable elements with high rates of remobilization in the presence of transposase. We investigated the post-integration behavior of the Mos1 mariner element in transgenic Aedes aegypti by examining both germ-line and somatic transpositions of a non-autonomous element in the presence of Mos1 transposase. Somatic transpositions were occasionally detected while germ-line transposition was only rarely observed. Only a single germ-line transposition event was recovered after screening 14,000 progeny. The observed patterns of transposition suggest that Mos1 movement takes place between the S phase and anaphase. The data reported here indicate that Mos1 will be a useful vector in Ae. aegypti for applications requiring a very high degree of vector stability but will have limited use in the construction of genetic drive, enhancer trap, or transposon tagging systems in this species.     

I.29 lymphoma cells express a nonmutated VH gene before and after H chain switch

The I.29 B cell lymphoma consists of IgM+ and IgA+ cells which express the same germ-line VH gene. IgA+ cells of the I.29 lymphoma were derived from the IgM+ cells by a typical H chain switch recombination event. The IgM+ cells can be induced with LPS to undergo H chain switching in culture. It has been proposed that the somatic hypermutation process is activated during H chain switch, since V genes expressed in IgG+ and IgA+ cells have more frequently undergone mutation than those expressed in IgM+ cells. We have investigated this question by sequencing VH genes expressed before and after H chain switch in the I.29 lymphoma. We have also sequenced the germ-line VH gene corresponding to the gene expressed by I.29 cells to determine whether the VH gene expressed in the IgM+ cells had already undergone somatic mutation. Our results indicate that somatic mutation was not activated in the precursor cell for the I.29 lymphoma, nor during isotype switch in I.29 cells. It is possible that cells of the I.29 lymphoma, or their precursor, have not received the signal which induces somatic mutation, or that I.29 cells belong to a subset of B cells that cannot be induced to undergo any (or much) somatic mutation.     

Stem cells and their progeny respond to nutritional changes during Drosophila oogenesis

Understanding how stem-cell proliferation is controlled to maintain adult tissues is of fundamental importance. Drosophila oogenesis provides an attractive system to study this issue since cell production in the ovary depends on small populations of observable germ-line and somatic stem cells. By controlling the amount of protein-rich nutrients in the diet, we established conditions under which the rate of egg production varied 60-fold. Using a cell-lineage labeling system, we found that both germ-line and somatic stem cells, as well as their progeny, adjust their proliferation rates in response to nutrition. However, the number of active stem cells does not appear to change. Proliferation rates varied fourfold; the remaining 15-fold difference in egg production resulted from different frequencies of cell death at two precise developmental points: (1) the region 2a/2b transition within the germarium, and (2) stage 8 egg chambers that are entering vitellogenesis. To initiate a genetic analysis of these changes in cell proliferation and apoptosis, we show that ovarian cells require an intact insulin pathway to fully upregulate their rate of cycling in response to a protein-rich diet and to enter vitellogenesis.