Cytological demonstration of mitotic crossing-over in man.

Quadriradial (QR) configurations from four different human lymphocyte metaphase samples have been analyzed: a patient with Fanconi's anemia; normal female cells X-irradiated with 150 or 200 R in S or G2; spontaneous QRs occurring in 13,584 metaphases; and cells from two sibs with Bloom's syndrome. That mitotic chiasmata are caused by crossing-over rather than by random breakage and reunion was concluded from the following observations: (1) In the spontaneous sample, mitotic chiasmata are about as frequent as all other QRs together. (2) The frequencies of mitotic chiasmata and of other QRs are not correlated in the different samples. (3) The break points in other QRs are situated at random relative to chromosome length, whereas the distribution of chiasmata is highly nonrandom. (4) Although the centromeres of chromatid translocations occur in alternate and adjacent positions with approximately equal frequencies, there are very few adjacent counterparts to mitotic chiasmata. These can best be interpreted as a result of an abnormal U-type rejoining of chromatids in a chiasma. (5) Chiasmata found in heteromorphic chromosome pairs show that crossing-over has, indeed, taken place.     

A high incidence of mitotic chiasmata in endoreduplicated Bloom's syndrome cells

Summary The frequency of mitotic chiasmata is compared in endoreduplicated and non-endoreduplicated Bloom's syndrome fibroblasts and in endoreduplicated Fanconi's anemia lymphocytes. The incidence of mitotic chiasmata in BS diplochromosomes is greatly increased over that in diploid BS cells and is much higher than in FA or normal diplochromosomes. The distribution of chiasmata among the BS diplochromosomes is not significantly different from that expected if crossing-over occurs at random along the chromosomes. This is in contrast to the distribution of chiasmata in chromosomes of diploid BS cells which is highly non-random among chromosomes and chromosome regions (Kuhn 1976). Mitotic crossing-over is increased in endoreduplicated cells from all sources compared to diploid cells, but the incidence is highest in endoreduplicated BS cells. This provides evidence against the idea that the high rate of mitotic crossing-over in diploid BS lymphocytes is primarily due to an increase in chromosome pairing. BS chromosomes apparently have a greater tendency to undergo mitotic exchange than normal or FA cells, both in diplo-chromosomes and in accidentally paired homologous segments in diploid cells.     

Mitotic chiasmata in human diplochromosomes

Summary Three placental tissue cultures of spontaneous human abortions showed an unusually high frequency of metaphases with diplochromosomes. In 62 such cells, nine configurations were interpreted as mitotic chiasmata between the two sister chromosomes of a diplochromosome. One U-type exchange between two sister chromosomes was also found. This differs significantly from the 1:1 ratio of adjacent and alternate exchanges in translocations, thus supporting the idea that mitotic chiasmata are in principle different from chromatid translocations. The hypothesis is put forward that the frequency of homologous exchanges is determined by the intimacy of pairing which ranges from meiotic pairing through sister chromatid association, through sister chromosome association in diplochromosomes to accidental pairing of homologous regions in diploid cells.     

Mitomycin C induced structural changes in heterochromatic regions of human chromosomes 1, 9, 16 and Y

Aberrations and variations in the heterochromatic blocks of chromosomes 1, 9, 16 and Y were found under the influence of mitomycin C in cultured lymphocytes of peripheral human blood. Lymphocytes were cultured during 96 hours, mitomycin C in final concentration of 0.3 mkg/ml was present in the culture during the latest 24 hours of culturing. Different changes in the heterochromatic regions of chromosomes were found in approximately 30% of cells: in 6.3% of cells mitotic chiasmata were indicated. In 9.5% of cells isolocus breaks were observed in heterochromatic region of chromosome 1 in segment 1q11. In the latter case this may be a fragile site detected under the influence of mitomycin C on the lymphocytes.     

Mitotic crossing-over and segregation in man

Summary Although clear genetic evidence of mitotic crossing-over is lacking in man, observations of mitotic chiasmata in normal cells (0.1–1 per 1000) and in Bloom's syndrome (BS) cells (5–150 per 1000) demonstrate its occurrence. That mitotic chiasmata are true exchanges is concluded from the occurrence of heteromorphic bivalents and the pattern of sister chromatid exchanges in mitotic bivalents. Several observations demonstrate that chiasmata are different in principle from chromatid translocations which simply happen to take place at homologous loci. For example, the ratio of adjacent exchanges to mitotic chiasmata is 1/20–1/60, whereas this ratio is approximately 1:1 for chromatid translocations. Furthermore, mitotic chiasmata make up a very high proportion of total quadriradials (QRs): 48% in normal untreated cells and 90% in BS cells.Close proximity of homologous chromosomes promotes mitotic crossing-over. Thus in normal diplochromosomes, the incidence is increased a hundred-fold as compared to diploid cells. However, closeness of homologues is not the only factor promoting crossing-over; the BS gene specifically promotes exchanges between homologous segments as shown by the roughly 15-fold increase of chiasmata in BS diplochromosomes as compared to normal diplochromosomes.Mitotic chiasmata are distributed extremely nonrandomly in different chromosomes and chromosome segments. The preferred sites are short Q-dark regions, 3p21, 6p21, 11q13, 12q13, 17q12, and 19p13 or q13 being veritable hot spots. Our preferred hypothesis is that the hot spots have higher gene densities than other regions. Consequently they are active and extended in interphase which would promote their pairing and chiasma formation.Segregation after mitotic corssing-over in satellite stalks can be demonstrated by means of distinct satellites. In a BS patient there were 31 different patterns for Q-bright satellites in 58 cells. Segregation after presumed crossing-over has also been seen in three dicentric chromosomes with one centromere inactivated. Recombination in satellite stalks in BS resulted in 12/58 cells homozygous for Q-bright satellites. In two of these cells, two chromosomes were homozygous for Q-bright satellites, and in one cell, three chromosomes were homozygous. This high degree of homozygosity which obviously applies to other chromosome regions too, may explain the high incidence of malignant disease in BS on the assumption that cancer is caused by recessive genes.     

Mitomycin C-induced sister chromatid exchange in X chromosomes of Bovidae

Sister chromatid exchanges (SCEs) in early- and late-replicating X chromosomes of seven female cattle (Bos taurus L.) and five female river buffalo (Bubalus bubalis L.) were studied in untreated lymphocytes and lymphocytes treated with mitomycin C (MMC). In the experiment, 577 SCEs on X chromosomes of MMC-untreated cells and 825 SCEs on X chromosomes of MMC-treated cells from both species were observed. No significant differences between the number of SCEs in early- and late-replicating X chromosomes were found even when singular species and subjects were considered.     

The analysis of exchanges in tritium-labelled meiotic chromosomes

The autoradiographic analysis of exchanges in tritium-labelled meiotic chromosomes is potentially a useful approach to the study of meiotic exchange events since this method differentially labels meiotic chromatids along their entire length. The main problem encountered in earlier autoradiographic studies is that of distinguishing label exchanges generated at chiasmata from label exchanges generated by sister chromatid exchange. This problem was overcome in the present study by the choice of a meiotic system (male meiosis of Stethophyma grossum) where chiasmata are limited to just one proximally localised chiasma in each bivalent. This system allows the positive identification of chiasma-generated label exchanges and demonstrates convincingly the origin of chiasmata through breakage and rejoining of homologous non-sister chromatids. Sister chromatid exchanges are also readily detected in labelled meiotic chromosomes of this species, where they occur with a mean frequency of 0.35 per chromosome. This frequency is similar to that found in mitotic spermatogonial cells and the exchanges are randomly distributed both within and between chromosomes. These features of meiotic sister chromatid exchanges suggest that they are unrelated to non-sister chiasmatic exchanges and they probably have no special meiotic significance.     

Segregation of tritium-labeled DNA at meiosis in chorthippus

A technique is described which gives well-defined label on meiotic chromosomes which incorporated tritiated thymidine two or more mitotic cycles prior to meiosis. It is shown that the distribution of label on meiotic chromosomes can be used to determine in which mitotic cycles label was incorporated. It is concluded that sister chromatid exchanges are common prior to meiosis, and that chiasmata do not show crossing-over of labeled material as is expected if the chiasmata are the result of breakage and rejoining or if chiasmata and crossovers are not related.     

A comparative study of mitotic and meiotic chromosomes of the Montandon's newt,Triturus montandoni (Urodela: Salamandridae) from Poland and Rumania

A karyological analysis was carried out on two populations ofTriturus montandoni, one from Poland and another from Rumania. For both samples, morphometric characteristics and C-banding pattern of mitotic chromosomes are provided. Only slight differences between specimens from two geographic localities were found. Data on chiasma frequency and distribution are presented for male meiosis. No sex-related heteromorphism was found and for none of the chromosomal arms was a consistent absence of chiasmata recorded. There was a relatively high proportion of spermatocyte metaphases I with chiasmata on both arms of all chromosomes in all specimens studied. It is concluded that there are no well-defined sex chromosomes in the chromosomal complement of the maleT. montandoni. The findings are compared with previous studies on chromosome morphology, C-banding pattern, and meiosis in closely related species,T. vulgaris andT. helveticus.     

Lack of synergistic effect between X-ray and UV irradiation on the frequency of chromosome aberrations in PHA-stimulated human lymphocytes in the G1 stage.

PHA-stimulated human lymphocytes in the G1 stage were irradiated with UV radiation and X-rays, and the cells were analyzed for chromosomal aberrations in the first mitotic division. The frequency of dicentric chromosomes after single X-irradiation in the G1 stage was about twice the yield in the G0 stage. No increase in the yield of dicentrics was observed after combined irradiation with UV and X-rays. This is contrary to the finding for G0 lymphocytes, where a 2-fold increase of chromosome aberrations was observed. UV irradiation of G1 lymphocytes induced chromatid-type aberrations whereas no significant yield of dicentric chromosomes was observed. This is in agreement with previous findings in Chinese hamster cells in the G1 stage [7]. Irradiation of G0 lymphocytes with UV radiation induce a low frequency of dicentric chromosomes. Thus, the present data indicate that the ratio between chromosome-type and chromatid-type aberrations is different in the G1 and G0 stages in human lymphocytes irradiated with UV radiation.     

Structural differentiation of the meiotic and mitotic chromosomes of the salamander,Ambystoma macrodactylum

The lampbrush chromosomes of the long-toed salamander, Ambystoma macrodactylum Baird, have been analysed and a map of the oocyte genome prepared. The location of C-bands and cold-induced-constrictions has been established in mitotic chromosomes and compared with the location of marker structures and chiasmata in several lampbrush bivalents. In the lampbrush chromosomes, C-bands are tentatively correlated with sphere-organizing loci and with regions of low chiasma frequency; cold-induced-constrictions are tentatively correlated with regions of high chiasma frequency. In general, in this salamander, C-bands do not coincide in position with cold-induced-constrictions. We have compared our results with those obtained by Callan (1966) in his investigation of chromosomes of the axolotl, Ambystoma mexicanum, and we present an analysis of the similarities and differences that are visible in the chromosome sets of these two ambystomatid species.     

Paradoxical changes in SCE frequencies persistently elevated in vivo, on exposure to a mutagen in vitro

Lymphocyte cultures from 4 individuals with persistently significantly elevated frequencies of sister-chromatid exchange (SCE) were examined with no treatment, and with 2 concentrations of mitomycin C. In each of the 4 cases, the mean level of SCEs in the untreated lymphocytes exhibited a paradoxical reduction in SCE frequency when exposed to the lower (0.005 microgram/ml) of the two doses of mitomycin C. At the second higher dose of mitomycin C (0.025 microgram/ml) the mean level of SCE/cell exceeded the untreated mean. When the distributions of SCE/cell were examined it appeared that the untreated cultures had two or more populations of cells; one was in the normal SCE frequency range, while the second population was in an elevated SCE frequency range. The paradoxical reduction in SCE frequency was apparently due to elimination of, or mitotic inhibition of cells in the highest range of SCE frequency, while a small elevation in SCEs was initiated in the cells with a normal SCE frequency. Thus, mean levels of SCE/cell can be misleading. This data suggests that new exposure to the same or a different genotoxic agent might possibly result in a misleading lowering of the mean SCE frequency.     

The effect of supernumerary chromosomes on meiosis in Puschkinia libanotica (Liliaceae)

The presence of the partly heterochromatic supernumerary chromosomes in pollen mother cells of Puschkinia libanotica raises the chiasma frequency in the A chromosome bivalents. The pattern of chiasma distribution along each of the five A bivalents was related to the DNA labelling pattern of mitotic chromosomes. Regions that showed heavy labelling at the end of the DNA synthetic phase had fewer chiasmata than lightly labelled regions. As this relation is the opposite to that found by Rees and Evans in another species we regard any correlation between labelling pattern and chiasma distribution as fortuitous.     

Hot spots and functional organization of human chromosomes

Summary Our working hypothesis is that the Q-darker human chromosome segments have higher gene densities than the bright regions. Especially prominent in this respect are six hot spots, the short Q-dark regions in 3p, 6p, 11q, 12q, 17q, and 19 (p or q), which have been chosen because their density of mitotic chiasmata is above 5. Chromosomes with gene-rich segments would act as trisomy lethals in very early embryos, whose spontaneous abortions would not be recognized. Containing active genes, the regions would be looped out in interphase and thus be more easily available for mitotic pairing and crossing-over.To test this hypothesis, correlations and partial correlations of the following parameters have been determined: the density of mitotic chiasmata, the number and density of localized genes, the incidence of trisomic abortions, the length of chromosomes, and their Q-brightness. Overall, the correlations and partial correlations agree with, but do not prove, the working hypothesis. Far stronger evidence for our hypothesis comes from the highly significant negative effect of hot spots on trisomic abortions which would act as a kind of trisomy lethal. The gene numbers on the hot-spot chromosomes as compared with the controls, on the other hand, are in the right direction, but the difference is not significant.This is paper No. 2161 from the Genetics Laboratory, University of Wisconsin. It was supported by National Institutes of Health (Washington) grants GM 22881, GM 15422-09, and, to Dr. Hans Ris, GM 04738; by grant IN-35P from the American Cancer Society, and by the U. W. Graduate Research Committee (Grant 101-4403). The photography was done by Mr. Walter Kugler, Jr.     

Giemsa banding of meiotic chromosomes

Applying a Giemsa staining technique to the meiotic chromosomes of Anemone blanda demonstrates that Giemsa bands similar to those seen in the mitotic chromosomes are discernible at all the principal stages of meiosis. The bands are not a product of the Giemsa procedure since they can be seen in unstained preparations using phase-contrast optics as chromocentres in interphase nuclei and as condensed regions in prophase chromosomes. That the bands seem to be permanent features of the nucleus, whether it is dividing or otherwise is an important consideration for understanding their nature and function. Bands and chiasmata do not coincide indicating on the one hand that chiasmata are not responsible for differences in banding patterns and on the other hand that the conservation of bands is an indication that they are either inert regions or specialised regions with considerable adaptive significance. These alternatives can only be resolved by genetical studies of the banding phenomena.     

Ecological correlates of chiasma frequency and recombination index of plants

This paper tests four theories of the maintenance of genetic recombination using published chiasma frequencies of 194 plant species representing 15 families of angiosperms. The theories are that recombination is favoured by environmental unpredictability, by fluctuating selection, by mutational load or by sib-competition. The level of genetic recombination was approximated by recombination index and by the number of excess chiasmata. Both measures were higher in animal-dispersed than in other species and increased as dispersal distance decreased. This association was found at all taxonomic levels. Chiasma frequency was not associated with life span of the species. Recombination index was lower in perennial than in annual species, but the reverse trend was observed among genera. Number of chiasmata per bivalent tended to decrease as the number of chromosomes increased, but this association was statistically insignificant at all taxonomic levels. No association was found between number of chiasmata per cell and nuclear DNA content.
These patterns did not support the theories that environmental unpredictability or fluctuating selection due to parasite pressure favour recombination, and they offered only very little support for the theory that recombination is favoured so that mutational load can be decreased. The only theory that was consistent with the observed data is the sib-competition theory, which suggests that genetic recombination is maintained so that the intensity of competition with sibs is reduced.     

Cytological, genetic and evolutionary functions of chiasmata based on chiasma graph analysis.

The nature of the chiasma as a cytological parameter for analysing cross-over was reexamined quantitatively by an improved chiasma graph method. It was reconfirmed in Mus platythrix (n =13) that interstitial chiasmata at diakinesis are distributed randomly and almost uniformly along bivalents except for the centromere and telomere regions. The size of these chiasma blank regions was consistently 0.8% of the total length of haploid autosomes in all chromosomes. There was a minimum value of chiasma interference distance between two adjacent chiasmata, which was constantly 1.8% in all chromosomes. The chiasma frequency at diakinesis was 20.1+/-2. 0 by the conventional method including terminal chiasmata. However, the primed in situ labeling technique revealed that terminal chiasmata were mostly telomere-telomere associations. From these data and also from recent molecular data we concluded that the terminal chiasma is cytologically functional for ensuring the normal disjunction of bivalents at anaphase I, but genetically non-functional for shuffling genes. The chiasma frequency excluding terminal chiasmata was 14.6+/-1.8. Reexamination of the chiasma frequency of 106 animal species revealed that the chiasma frequency increased linearly in proportion to the haploid chromosome number in spite of remarkable difference in their genome size. The increase in chiasma frequency would be evolution-adaptive, because gene shuffling is expected to be accelerated in species with high chromosome numbers.     

Measurement of micronuclei by cytokinesis-block method in cultured Chinese hamster cells: comparison with types and rates of chromosome aberrations

The cytokinesis-block method of Fenech and Morley (1985) has been tested for the enumeration and characterization of micronuclei in exponentially growing Chinese hamster cells in culture. The consistent dose-response relations were obtained in cultures treated with mitomycin C, caffeine and colcemid. Comparison with the chromosome aberration frequencies indicated that approximately 30% of the acentric chromosomes are expressed as micronuclei in the mitomycin C and caffeine treated cells. The size distribution of the micronuclei suggested that the base-line frequency of micronuclei is mainly a reflection of mitotic dysfunctions rather than chromosome structural aberrations.     

Induced Robertsonian fusions and tandem translocations in mammalian cell cultures.

Cultures of a cattle cell line and a Peromyscus eremicus cell line recovering from a pulse-treatment with mitomycin C, actinomycin D, 33258 Hoechst, and nitrosoguanidine exhibited translocations between chromosomes at the centromeric regions (Robertsonian fusions) as well as between centromere and telomere and between telomeres (tandem translocations). The frequency of Robertsonian fusions was found to be dose-dependent and duration-dependent with the mitomycin treatment. Biarmed chromosomes resulting from fusions may be monocentric or dicentric. Analyses of clones isolated from treated cells suggested that fused chromosomes may perpetuate in the cell populations.