The internal order of the interphase nucleus

Summary This paper has two parts. The first one is theoretical, whereas in the second, some experimenteal results are reported. Part 1: Theoretical Considerations. Comings' considerations on an ordered arrangement of chromatin in the interphase nucleus are used as a basis for further investigations and calculations in order to establish a preliminary model of the interphase nucleus. Information on the amount of DNA of a diploid human nucleus, on the degree of spiralization of chromatin threads found in electron microscopy, and measurements of salivary gland chromosomes was used to estimate the lengths of the entire interphase chromosomes. The number of fixing points-pores—was indirectly calculated proposing a model of an internal order of the chromatin threads. This number was found in concord with a direct calculation of the number of pores in the nuclear membrane based on results from electron microscopy. Part 2: Experimental Results and Discussion. In the second part of this study, an approach was made as to how to arrange chromosomes and chromosome segments in their proximity to each other. Results of cytogenetic studies of newborn babies and abortions, of cells from patients with Bloom's syndrome and Fanconi's anemia and normal cells treated with Mitomycin C and Trenimon, are thought to be informative under certain suppositions for the problem, which chromosome or chromosome parts are situated in proximity to each other. The symmetrical and equal interchanges seen, for example, in Bloom's syndrome are an indication of somatic pairing during the time of reunion. Therefore, the unequal interchanges in the same syndrome in which different chromosomes are involved should give evidence for proximity of nonhomologous chromosomes. Arguments for and against a temporal and spacial hypothesis for somatic pairing are discussed. The differing frequencies of chromosomes involved in Robertsonian translocations in man are informative for proximities of satellite regions at the nucleolus. Nucleolus and sex chromatin could be used as fixed points in a model of the interphase nucleus in which finally the absolute localization of the chromosomes will be discovered. The discussion points out promising methods for further investigations on the subject and mentions problems which could be attacked if the approach described here leads to a model of internal order in the interphase nucleus.This work was supported by the Deutsche Forschungsgemeinschaft within the Sonderforschungsbereich 35, Klinische Genetik.     

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.     

Effects of mitomycin C on sister chromatid exchange in normal and Bloom's syndrome cells

Bloom's syndrome lymphocytes, which are characterized by a high incidence of sister chromatid exchanges (SCE: 80.6 per cell), were treated with mitomycin C (MMC) and the effect of the chemical on SCE frequency compared with that in normal cells. Raising the concentration of MMC from 1 X 10(-9) to 1 X 10(-7) g/ml led to about 10-fold increase (61.7 SCE per cell) in the SCE frequency over the base line in normal lymphocytes (6.4 SCE per cell), though chromosome aberrations remained at a relatively low frequency. MMC caused about a two-fold rise in SCE in cells of Bloom's syndrome (128.8 SCE at 10(-9) g/ml; 139.3 SCE at 10(-8) g/ml). The frequency of chromosome aberrations in Bloom's syndrome cells at concentrations of MMC of 1 X 10(-9) and 1 X 10(-8) g/ml was 0.350 and 0.825 per cell, respectively, and low when compared to the increased number of SCE. The increased frequency of SCE in normal and Bloom's syndrome cells is in contrast to the reported findings with cells from Fanconi's anemia and xeroderma pigmentosum. The distribution of SCE in MMC-treated normal cell correlates with that of spontaneous SCE in cells of Bloom's syndrome.     

Relationship of spontaneous chromosome instability and sister chromatid exchanges in Fanconi's anemia

The frequency of spontaneous instability of lymphocyte chromosomes of the first 2 mitoses, the rate of sister chromatid exchanges (SCEs), and the proliferative kinetics of lymphocytes were studied in a 6-year-old girl with Fanconi's anemia (FA) and in 4 healthy donors. The frequencies of aberrant cells and the total number of chromosome breaks in the FA patient decreased with cell transition from the first to the second mitosis. The FA lymphocytes had a slower proliferative kinetics and the level of SCEs was higher as compared with control. The probability of chromatid deletions at the sites of SCEs localization and in the dark and light stained chromatids was unequal. 33.8% of chromatid breaks were associated with SCEs. The data point to the relationship between SCEs and spontaneous chromosome instability in AF cells.     

Chromosome breakage and rejoining of sister chromatids in Bloom's syndrome

The occurrence of chromosome breaks and reunion of sister chromatids in lymphocytes of two patients with Bloom's syndrome has been compared with those found in X-rayed and control cells. The distribution of breaks in BS is non-random both between and within chromosomes, the centric regions of certain chromosomes being preferentially involved. The following working hypotheses are put forward: When chromosome breaks in human lymphocytes occur in G₀— G₁, practically no sister chromatid reunion (SCR) takes place, whereas ends created by an S—G₂ break show a considerable tendency to SCR. We propose further that chromosome aberrations in BS mainly result from breaks in S—G₂, including possible U-type rejoining of sister chromatid exchanges. Fragments extra to an intact chromosome complement result from a chromatid break or an asymmetrical chromatid translocation in a previous mitosis.     

Sister chromatid exchanges and chromatid interchanges in bloom's syndrome.

A comparison is made between the incidences of sister chromatid exchanges (SCE) per chromosome and group of chromosomes and breakage, visible at metaphase like open gaps, breaks, and breaks involved in chromatid interchange formation (CI) in Bloom's syndrome. It can be shown that the two levels of breakage SCE and CI are not correlated as to the locations. The discussion deals with possible interpretations of preferential breakage and reunion at certain homologous chromosomes and the difficulties today to understand SCEs.     

Increased sister chromatid exchange in bone marrow and blood cells from Bloom's syndrome.

Bone-marrow cells from a patient with Bloom's syndrome cultured for 48 h in the presence of BudR exhibited a striking increase in the number of sister chromatid exchanges (SCEs) in comparison to that in the marrow cells of a patient with treated polycythemia vera (PV). Thus, it appears that an increased incidence of SCE in Bloom's syndrome occurs in various differentiated types of cells, not just blood lymphocytes, and constitutes the syndrome's most characteristic cytogenetic feature. In contrast, the incidence of SCE was not increased in marrow cells and lymphocytes of the particular PV patient studied here, whose cells did exhibit increased numbers of chromatid and chromosome gaps and breaks, presumably as result of the patient's earlier treatment. An increased frequency of SCE was demonstrated in Bloom's syndrome lymphocytes using both a technique based on BudR incorporation and one based on labeling with tritated deoxycytidine. This observation constitutes evidence against the increase of SCE being due to an unusual reaction to BudR. By conventional cytogenetic techniques, chromosome instability, including chromatid and chromosome breaks, but no homologous chromatid interchanges were also recognized in Bloom's syndrome bone-marrow cells incubated in vitro (without BudR) for either 1.k or 16 h. This observation points to the existence of chromosome instability in vivo.     

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.     

Bloom's syndrome. Discussion of the diagnosis concerning two cases of terminal leukemia in a sibship (author's transl)

Two brothers developed acute leukemia, one at the age of 7 months and the other at the age of 14 months. Both suffered from a staturoponderal retardation and the same malformation syndrome. The karyotype carried out only on the second child revealed breaks and chromatid changes. A diagnosis of Fanconi's anaemia can be discarbed since no blood cytopenia preceded the leukemia. Finally, the diagnosis of Bloom's syndrome prevailed despite the absence of telangiectatic erythema and the atypical chromosomal anomalies.     

Mitotic chiasmata and other quadriradials in mitomycin C-treated Bloom's syndrome lymphocytes

Mitotic chiasmata and other quadriradials (QRs) were studied by Q-banding in mitomycin C-treated and untreated lymphocytes from two sibs with Bloom's syndrome. The frequency of chiasmata was very significantly increased by the mitomycin treatment in cells from both sibs. Chiasmata occurred throughout the chromosomes, but were favored in Q-dark regions, particularly at borders between dark and light regions (Kuhn, 1976). No significant difference was found in the distribution of chiasmata among chromosome regions in treated and untreated material. This differs from the reported action of mitomycin C on cultured lymphocytes of normal persons, where chiasmata are concentrated at secondary constrictions and centromeres. Adjacent counterparts to mitotic chiasmata, and chromatid translocations between non-homologous chromosomes, also occurred in the treated material, but with a much lower frequency than mitotic chiasmata. This again differs from the effects of mitomycin C on lymphocytes of normal persons, where chiasmata account for 20% or less of total QRs.This is paper No. 2054 from the Genetics Laboratory, University of Wisconsin, Madison     

Nonrandom distribution of chromosome breaks in cultured lymphocytes of normal subjects

Summary Breakpoint distribution was studied from cultured lymphocytes on 7653 metaphases from 524 subjects whose karyotypes were normal. The mean break rate was 5% in both sexes. The frequency increased significantly after 40 years and varied during the year. The location of the breaks was very different from the expected random distribution. The break frequency for each chromosome was different according to the type of break (chromatid, simple chromosomal and chromosomal involving rearrangements). The location of the breaks was also studied according to the type of band and with respect to the centromere. A comparison between spontaneous breaks, X-ray induced breaks, breaks in Fanconi's anemia and in congenital rearrangements, show very significant differences.     

Origin of symmetrical triradial chromosomes in human cells

We have collected 23 sporadic symmetrical triradial chromosomes (plus one D with duplicate satellites), 22 from cultured lymphocytes and one from a bone marrow cell. Fifteen triradials were from patients with Bloom's syndrome, and two from a Fanconi's anemia patient. The following chromosomes and chromosome groups were involved: 1, 2, 3, 4, 5, C (11 identified), D, and 17. The branchpoints were localized nonrandomly. Regions in or near centric heterochromatin were often involved. Some of the branchpoints are regions which also contain a high number of mitotic chiasmata. When the present sporadic triradials combined with those from the literature were compared with triradials with branchpoints in the fragile regions, the localized branchpoints were different in these two groups. Our conclusion that most — possibly all — symmetrical triradials are caused by partial endoreduplication is based on the following observations: the shape of the triradials which shows that the extra segments are paired with their intact sister chromatids and not with each other; the failure of X-rays in G₂ to increase the incidence of symmetrical triradials; the fact that in some cases the end of the extra segment is joined to its intact sister chromatid; and the occurrence of duplicate satellites.     

Cytogenetischer Befund und Ätiologie bei Fanconi-Anämie

Summary In addition to findings in four cases of Fanconi's anemia with hexokinase deficiency recently reported we are able to show cytogenetic results in a further case without any defect in carbohydrate metabolism.Cultures were made from peripheral blood. 30% of the mitoses showed chromatid type aberrations. Although the findings in this case no. 274 proved to be similar to those of the other patients, there are some differences, however.In this case 1. the number of chromatid breaks is smaller, 2. the number of mitoses with several coincidental aberrations is lower, 3. the number of chromatid exchanges in higher and 4. mostly the reunion is the only aberration within the metaphase (7 out of 10). It is shown that most of the cells with two chromatid breaks were able to rejoin. In numerous cells with hexokinase defect, however, several breaks without any sign of rejoining were found.This means, that in case 274 the reunion system is not damaged in the same way by an unknown genetic defect as in cells with the hexokinase deficiency. This also means, that these two types of Fanconi's anemia can be detected by different cytogenetic findings. The absence of cells with accessory nuclei in the bone marrow film is discussed in this respect, too.Our suggestion is based on results of experimental cytogenetics. Different frequencies of chromatid exchanges found in experiments on the influence of chemical mutagenes and irradiation according to the special lesion on the rejoining system are discussed.

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Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Effects of X-irradiation in G1 and G2 on Bloom's syndrome and normal chromosomes

Summary The X-ray sensitivity of chromosomes from a Bloom's syndrome patient and a normal control was compared in G₁ and G₂. There was no significant difference in the number of aberrations induced by irradiation in G₁. An increased sensitivity of the BS chromosomes was found in G₂. The frequency of mitotic chiasmata in the BS cells was not increased by the G₂-irradiation, even though the frequency of chromatid translocations was much increased. This provides further evidence for the fundamental difference of these two phenomena. Evidence from the types of aberrations induced suggests that there is no appreciably increased frequency of pairing of homologous chromosomes in the BS cells over that in normal cells.     

Frequency and types of induced and spontaneous chromosome aberrations in relation to cell kinetics

Summary Induced and spontaneous structural chromosome aberrations (SCA) were studied in a child accidentally radiated with a high dose of ¹⁹²Ir, and in three sibs with Fanconi's anemia, analyzing by separate first division metaphases (FDM) and second division metaphases (SDM). The results showed that the number of SCA, number of cells with aberrations, and SCA per cell were markedly higher in FDM in all patients.Furthermore, for some type of structural changes like dicentric chromosomes and chromatid interchanges, the differences were particularly striking. The importance of ascertaining FDM identified with proper techniques, for the study of the clastogenic effect of environmental agents and some aspects related to the differences in cytogenetic features found in diverse tissues in Fanconi's anemia are discussed.     

The effect of procarbazine on the chromosomes of normal and malignant mouse cells.

The effects of the cancer drug methylhydrazine derivative procarbazine (PC) on the chromosomes of normal and malignant cells in the mouse strains Swiss Albino, CF1, and BDF1 have been analyzed. PC broke chromosome in the hypotetraploid Ehrlich and the diploid P388 ascites tumors. Practically all breaks seemed to be of the G2 type and, as far as could be determined, took place in the quinacrine-dark or the corresponding Giemsa-light regions. The vast majority of the broken ends had rejoined to form chromatid translocations. No increase in chromosome breaks were seen in any of the normal tissues treated in vivo: spleen, bone marrow, spermatocytes, or spermatogonia (in this tissue the cells were not counted). The chromosomes of the Ehrlich ascites tumor have been studied by means of both Q-banding and G-banding. Very few, if any, chromosomes seem to have an exact homologue or to correspond to any of the normal mouse chromosomes.     

Chromosome characteristics of X-linked mental retardation. II. Autosomes

The frequencies of chromosome and chromatid breaks and gaps were studied in blood lymphocytes of three groups of individuals: 21 males with X-linked mental retardation characterized by fragile X chromosome; 52 males with non-differentiated X-linked mental retardation having no fra(X) chromosome in their cells; 15 intellectually normal males. The lymphocytes were cultured both in medium 199 and in Eagle's medium supplemented with fluoro-deoxyuridine. The significantly higher frequencies of various autosomal lesions were observed in the individuals with the fragile X chromosome syndrome and in those with mental retardations without fra(X) chromosome, in comparison with normal males. The significant difference in some autosome lesions was also found between both groups of the patients. The distribution of chromosome lesions in autosomes of different groups was significantly higher in chromosomes A and lower in groups B, E, F and G, than expected in accordance with their relative length in the haploid set. In all the groups of individuals studied, the predominant localization of chromosome and chromatid breaks and gaps was observed in fragile sites 1p31, 3p14, 6q26 and 16q23.     

Cytogenetic investigations in a new case of Bloom's syndrome

Summary Cytogenetic studies of an 8-year-old caucasian girl with typical but mild manifestation of Bloom's syndrome showed a characteristic increase of homologous chromatid translocations and prematurely condensed chromosomes. The average frequency of sister chromatid exchanges (SCE) in lymphocytes with 133 was much higher than in skin fibroblasts with 49. The inter- and intrachromosomal distributions of SCE in lymphocytes were analyzed.Prof. Dr. H.-R. Wiedemann to his 60th birthday.     

Deoxyribonucleoside triphosphate pool levels in three cell strains of human chromosome instability syndromes: ataxia telangiectasia (GM2052), Bloom's syndrome (GM1492), and Fanconi's anemia (GM368)

Deoxyribonucleoside triphosphate (dNTP) pool sizes were determined in cell strains derived from patients with the genetic diseases ataxia telangiectasia (GM2052), Bloom's syndrome (GM1492), and Fanconi's anemia (GM368), and were compared to the dNTP pools in a normal human fibroblast cell strain (253/79). In addition, the effect of deoxythymidine on both dNTP pool levels and cell growth was examined. The three mutant cell strains differed only slightly from the normal cell strain. The cellular characteristics of the cell strains, such as chromosome instability, are apparently not an effect of dNTP pool imbalance.     

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.