Etude de la distribution générale des 46 chromosomes dans les cellules humaines en métaphase

Summary This study, based on the square distances of chromosome centromeres from the center of a cell, shows after circular transformation, that the general dispersion of the 46 chromosomes is uniform, except on the periphery of the cell. It is found that the chromosomes taken separately have not a random distribution, but have peculiar positions. In males, chromosomes 1, 13-14-15 and 21–22 tend to lie nearer the middle of the nucleus, while chromosomes, Y, 6-X and 4–5 tend to lie nearer the periphery. In female mitoses the chromosome 13-14-15, 21–22 and 19–20 and 19–20 have a more central position, while chromosomes 4–5, 3, 2 and 16 tend to lie nearer the periphery.

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The ordered arrangement of chromosomes in the Chinese hamster spermatocyte nucleus

Summary The question of chromosome distribution in the mammalian nucleus is addressed, and data are provided in support of the ordered arrangement of chromosomes in the Chinese hamster spermatocyte. Testicular cells were dispersed and air-dried without prior fixation, then stained and karyotyped. The position of chromosome telomeres in 217 pachytene spermatocytes was determined in relation to four concentric rings which equally divided the nuclear area. The distribution of telomeres showed a progressive decline from the central to the peripheral rings. This was particularly pronounced for chromosomes 1–7, but was reversed for the XY chromosomes. The distribution of the total as well as of the individual chromosomes was significantly different from that expected on the basis of random distribution. The only exceptions to this were chromosomes 8–10, which exhibited random distribution. Thus, while chromosomes 1–7 had a central position, the XY pair had a peripheral localization. The mean ring position appeared to be related to chromosome length, except for the XY chromosomes, suggesting that chromosome length may determine chromosome position.     

The spatial distribution of chromosomes in metaphase neuroblast cells from subspecific F1 hybrids of the grasshopper Caledia captiva

The spatial distribution of chromosomes has been analysed in radial metaphase neuroblast cells in F₁ hybrid embryos generated by crossing individuals of the Moreton and Torresian (TT) chromosomal taxa of the grasshopper Caledia captiva. The Moreton individuals were of two kinds depending on whether they carried an acrocentric X (MAX) or a metacentric X (MMX). No significant associations were detected between any pair of homologous chromosomes in either male or female (MAX x TT) and (MMX x TT) F₁ hybrids. This result was supported by data which showed that the mean separation between homologues is greater, although not significantly so, than the mean separation between non-homologous chromosomes within the two Moreton genomes. Indeed, in a number of cases, genome separation was clearly observed in radial metaphase preparations from these F₁ hybrids. By comparison the analysis of pairwise associations between non-homologous chromosomes within the MMX and MAX Moreton genomes revealed a number of significant associations and dissociations which strongly suggests that at least some chromosomes in these genomes are organised non-randomly at metaphase. Of particular interest was the highly significant X-5 association in the MMX genome since in a previous study X-5 rearrangements were found to occur repeatedly among different backcross progeny involving Moreton x Torresian F₁ hybrids. Additionally a comparison of the organisation of chromosomes in the MAX and MMX genomes, which differ primarily by the type of X chromosome, revealed that in a number of cases pairs of chromosomes are arranged very differently with respect to each other. The distribution of chromosomes on the hollow spindle was also analysed to investigate whether a specific spatial ordering of chromosomes exists within these Moreton genomes based on the association of pairs of short arms and pairs of long arms of most similar length (the Bennett model). The twelve chromosomes in both genomes were uniquely ordered in a single chain. However, because of computing limitations, only the ordered arrangement of chromosomes 1–10 was investigated. An analysis of 48 cells in the MMX and 38 cells in the MAX genomes showed that the predicted order in the ten chromosome sub-set in each genome did not rank in the top 20% of the 181,440 possible orders. This suggests that, although there is a good evidence that some non-homologous chromosomes may be associated non-randomly at metaphase in these genomes, they do not appear to show a specific, ordered arrangement as predicted by the Bennett model. The significance of the observed non-random organisation of chromosomes in the MMX and MAX genomes is discussed in relation to the generation of novel chromosome rearrangements in Moreton x Torresian F₁ hybrids and the evolution of the Moreton and Torresian genomes.     

Karyotype variation in Drosophila birchii

Drosophila birchii, a member of the melanogaster species group of the subgenus Sophophora, is common in the tropical rain forests of the Australia-New Guinea areas. Chromosome squashes are easily prepared from the larval ganglion cells and the sex chromosomes are readily recognizable. The species exhibits a remarkable karyotype variation. The metaphase plate figures, in general, show two pairs of V's, one pair of dots and one pair of sex chromosomes. Variations in metaphase chromosome morphology are found in the X (with four types), the Y (with three types) and chromosome IV (with two types). Chromosomal interchanges between X- and Y-chromosomes Type I are postulated to be involved in the differentiation of sex chromosome morphology while the modification of chromosome IV seems likely to be a result of the acquisition of extra heterochromatin. These chromosome types form seven distinct metaphase plate figures, all encountered in wild populations, thus giving D. birchii the most variable karyotype in the genus Drosophila.     

Incorporation of proteins labeled with H3-lysine into chromosomes of human leucocytes cultured in vitro

The experiments were carried out on human leucocytes cultured in vitro. We studied the distribution of silver grains over metaphase chromosomes after pulse-labeling of cells with H³-lysine in S- and G2 phases. It was found that the grain number per chromosome of the pairs No. 1–3, 13–15 is proportional to their lengths. The probability of incorporation of labeled proteins into each of the homologous chromosomes of the first pair is equal to 0.5 found from the results of statistical analysis of silver grain counts. In cells with karyotype XXX labeled in late-S, the grain number per chromosome in the subgroup 6-X-7 is uniform. In these cells there is no difference in labeling densities among chromosomes of the group A. The data obtained suggest that the formation of the protein component in autosomes of different groups as well as in homologous autosomes and sex-chromosomes proceeds simultaneously and at equal rate.     

Quantitative studies on the arrangement of human metaphase chromosomes

Summary The spatial relationships between the homologous pairs of chromosomes in the normal human colcemid-treated metaphase plate were tested by two different mathematical approaches: (a) determination of the distances between the centromeres of the homologous chromosomes compared to the mean distance of all centromeres of the mitosis in question; (b) measuring the distances of the different chromosomes from the center of the mitosis.The following results were obtained: (1) The arrangement of human metaphase chromosomes does not follow a normal distribution; the distribution is narrower and taller, probably due to an impairment of free chromosome spreading by the cell membrane. We believe that only in membraneless mitotic cells should the chromosome-spread correspond to a normal distribution under the same preparation conditions. (2) There is a positive correlation between decreasing chromosome size and decreasing mean distance between homologous chromosomes. (3) A close positive correlation exists between increasing chromosome size and increasing distance to the barycenter of the mitosis. (4) There is also a close positive correlation between the distance of homologous chromosome pairs and their distance from the center of the mitosis, i.e., with increasing distance from the center of the mitosis, the distance between the homologous partners increases. (5) The following statistically significant deviations from these rules could be established: (a) The large acrocentric chromosomes are closer associated, as one would expect from their size, probably due to their participation in the nucleolus organization; (b) in the female cell one of the two X chromosomes has an extremely peripheral localization; the X chromosomes are furthest apart of all pairs of homologous chromosomes; (c) the chromosome pairs 6 and 8 are relatively close together in spite of their peripheral position, suggesting a truc close association of the homologus partners; (d) the chromosome pair 18 has a more peripheral position than expected, and a relatively large mean distance between the homologous partners; (e) the chromosome pair 1 has a much more central position and a closer association than is expected from its size.     

The relative arrangement of chromosomes in mitotic interphase and metaphase in Haplopappus gracilis

The relative position of mitotic metaphase chromosomes in Haplopappus gracilis is studied by direct observation of undisturbed metaphase cells in root tips: the homologous chromosomes lay always adjacent to each other, whereas the relative position of the pairs is not constant. — The relative position of interphase chromosomes is inferred from the frequency of radiation-induced mutual rearrangements between any possible pair of chromosomes. — It is concluded that the relative position of interphase chromosomes is reflected by the relative position of metaphase chromosomes in Haplopappus gracilis.     

DNA replication sequence of human chromosomes in blood cultures

Summary The pattern of labelling over the chromosomes, the chronology of chromosome duplication and the duration of the S and G ₂ periods in the leukocytes from 6 normal females and 5 normal males, have been studied by using a combination of pulse and continuous tregtments with thymidine-H³. According to the criteria used to analyse the results it is suggested that the S period begins 15 to 20 hours and finishes 5 to 3 hours before the cells reach the metaphase stage. The S period could be subdivided into the four phases S₁ to S₄.The first chromosomes to replicate were Nos. 1, 3, 5 and X followed by the Nos. 2, 4 and several chromosomes of groups 6–12, 13–15 and 19–20. Later the pairs 16, 17, 18 and the chromosomes of group 21–22 replicated. Chromosome Y in the male was the last to replicate, beginning its duplication when all the other chromosomes had reached the intermediate S stage.The earliest chromosomes to finish the duplication were Nos. 19, 20 and 21 followed by Nos. 16, 17, 18, 22 and the chromosomes of group 13–15. Afterward and at about the same time the replication of pairs 2, 4, 6, 8, the X and Y chromosomes in the male and one X chromosome in the female concluded. The other X chromosome in the female was the last to end its duplication appearing totally labelled until the final stage of the S period.Replication of the long and medium size chromosomes begins at localised regions, then extends over the total length of the chromosome and at the end of the S stage takes place only in small zones different from those replicating early.Asynchrony between homologous chromosomes was observed at the beginning and at the end of the S period.     

Dynamic bonds and polar ejection force distribution explain kinetochore oscillations in PtK1 cells

Duplicated mitotic chromosomes aligned at the metaphase plate maintain dynamic attachments to spindle microtubules via their kinetochores, and multiple motor and nonmotor proteins cooperate to regulate their behavior. Depending on the system, sister chromatids may display either of two distinct behaviors, namely (1) the presence or (2) the absence of oscillations about the metaphase plate. Significantly, in PtK1 cells, in which chromosome behavior appears to be dependent on the position along the metaphase plate, both types of behavior are observed within the same spindle, but how and why these distinct behaviors are manifested is unclear. Here, we developed a new quantitative model to describe metaphase chromosome dynamics via kinetochore–microtubule interactions mediated by nonmotor viscoelastic linkages. Our model reproduces all the key features of metaphase sister kinetochore dynamics in PtK1 cells and suggests that differences in the distribution of polar ejection forces at the periphery and in the middle of PtK1 cell spindles underlie the observed dichotomy of chromosome behavior.     

The electron-microscopic structure of nucleoprotein fibrils from metaphase chromosomes treated with salt

The diameter of nucleoprotein fibres of metaphase chromosomes is sensitive to salt concentrations. Treatment of human lymphocyte cells in metaphase with a hypotonic medium and spreading them on a water surface causes swelling of the chromosome fibres from 150–180 Å to 230–250 Å. Treatment of the chromosomes with 0.15–0.45 M NaCl, a concentration at which histones are not yet removed from the nucleoprotein complexes, apparently does not affect the chromosome structure. Treatment with NaCl solutions between 0.6 M and 2.0 M NaCl leads to a progressive extraction of the chromosomal proteins and decreases the diameter of the chromosome fibres to 80–100 Å and less.Dedicated to Prof. Dr. A. Butenandt on the occasion of his 70th birthday.     

The behavior of allocyclic chromosomes in Bloom's syndrome

The behavior of individual allocyclic chromosomes has been analyzed in lymphocytes of a sister and a brother with Bloom's syndrome. Of 4,633 diploid cells, 115 showed allocyclic chromosomes, and 74 of these had 44, 45 or 46 normal metaphase chromosomes accompanied by one or two allocyclic chromosomes. Of 56 tetraploid cells, 9 contained such chromosomes. The allocyclic chromosomes appeared pulverized or extended corresponding to S or G₂ PCC. We have proposed the hypothesis that individual allocyclic chromosomes do not, as a rule, come from micronuclei, as has often been assumed, but have been left behind in their cycle. This would be caused by a mutation or deletion of a hypothetical coiling center situated near the centromere of each chromosome arm. The following observations agree with our explanation but less well or not at all with the idea of micronuclei: (1) In only 9.6% of the cells does the allocyclic chromosome lie at the edge of the metaphase plate. (2) In 24 cells a part of a chromosome is pulverized while the rest is in metaphase. (3) Both a pulverized and an extended chromosome were present in the same cell. (4) A pulverized acrocentric is often nose-to-nose with a normal D or G chromosome. (5) No allocyclic chromosomes corresponding to G₁ PCC have been found in our material. (6) When a ring is replaced by an allocyclic chromosome, it is usually a member of a 46-chromosome complement. Furthermore, the occurrence of allocyclic chromosomes is correlated with that of other chromosome anomalies which do not follow a Poisson distribution. Allocyclic chromosomes are also more frequent (16%) in tetraploid than in diploid cells (2%).     

Chromosomal localization of the human histamine H1-receptor gene

We have assigned the human histamine H₁-receptor gene to chromosome 3 by Southern blot analysis of a chromosome mapping panel constructed from humanhamster somatic cell hybrids. This assignment was confirmed by in situ hybridization on metaphase chromosomes and involved bands 3p14–p21.     

Do individual allocyclic chromosomes in metaphase reflect their interphase domains?

Summary Individual S phase allocyclic chromosomes have been analyzed in Bloom syndrome lymphocytes, in cells with an r(9), and in hypotetraploid Ehrlich mouse ascites cells treated with 1-methyl-2-benzyl hydrazine. On the basis of the following observations, we conclude that such chromosomes more or less reflect their domains in interphase: (1) The S phase allocyclic chromosomes have the same structure as S phase prematurely condensed chromatin (PCC) in fused cells; in other words they form limited areas of chromatin dots; (2) the allocyclic chromosome is the only chromosome in a metaphase plate which synthesizes DNA simultanneously with interphase nuclei; (3) the size of the allocyclic chromosomes is related to the size of the corresponding metaphase chromosome; and (4) the S phase allocyclic chromosomes resemble closely the chromosome domains in interphase made visible with biotinylated human DNA. A variety of evidence shows that most allocyclic chromosomes are simply left behind in their cycle, which presumably is caused by a deletion or inactivation of a hypothetical coiling center situated on each chromosome arm.     

Effects of griseofulvin on mitosis in PtK1 cells

The concentration dependent effects of griseofulvin (GF) on mitosis in PtK₁ cells were studied using a combination of time lapse cinematography and polarization and electron microscopy. Low concentrations of GF (4×10^–5 M) allowed a substantial number of cells to enter and complete an apparently normal mitosis. At higher concentrations of GF (1×10^–4 M and 2.5×10^–4 M) all cells entering mitosis were arrested. Typical c-mitotic chromosome arrays were observed at 1×10^–4 M GF with microtubules present but no spindle formed. At 2.5×10^–4 M GF chromosomes did not orient toward a common center to form a c-mitotic figure, but instead remained in a loosely clustered grouping at the center of the cell. Electron microscopy showed microtubules to be absent but revealed an irregularly shaped electron dense cloud around the centrioles. Quantitative polarization microscopy of metaphase cells perfused with GF showed rapid loss of spindle birefringence after exposure to the drug. Coinciding with loss of birefringence the spindle shrank rapidly with a pronounced shortening of pole to pole distance.     

Light and electron microscopy of rat kangaroo cells in mitosis

Kinetochores in rat kangaroo (PtK₂) cells in prophase of mitosis are finely fibrillar, globular bodies, 5000–8000 Å in diameter. Sister kinetochores are attached to opposite lateral faces in the primary constriction of chromosomes. No microtubules (MTs) occur in prophase nuclei. During prometaphase the ball-shaped kinetochores differentiate into trilaminar plaques. An outer kinetochore layer, less electron dense than chromatin, appears first in the fibrillar matrix. The inner layer, continuous with, but more electron dense than the chromosome, is formed later. Kinetochore-spindle MT interaction is evident at the very beginning of prometaphase. As a result, kinetochore shape is very variable, but three types of kinetochores can be distinguished by fine structure analysis. A comparison of kinetochore structure and chromosome position in the mitotic spindle yielded clues regarding initial orientation and congression. At the time the nuclear envelope (NE) breaks down chromosomes near asters orient first. Chromosomes approximately equidistant from the two spindle poles amphi-orient immediately. Chromosomes closer to one pole probably achieve mono-orientation first, then amphi-orient and congress. In normal metaphase all the chromosomes lie at or near the spindle equator and kinetochores are structurally uniform. Paraxial and para-equatorial sections revealed that they are trilaminar, roughly circular plaques of 4000–6000 Å diameter. Inner and outer layers are 400 Å, and the electron translucent middle layer which separates them is 270 Å thick. From 16 to 40 MTs are anchored in the outer layer. In cold-treated cells the kinetochores are trilaminar, but in colcemid-treated cells the inner layer is lacking. Both kinetochores and their MTs are disorganized beginning in late anaphase. In telophase the inner layer persists for some time as an electron dense patch apposed to the NE, while the outer layer disintegrates.     

Karyotype analysis of Eucinostomus argenteus, E. gula, E. harengulus, and Eugerres plumieri (Teleostei, Gerreidae) from Florida and Puerto Rico

The karyotypes of four gerreids of the western Atlantic Ocean are documented. A diploid chromosome complement of 48 telocentric chromosomes was found in the four species (2N=48t, fundamental number FN=48). No differences were detected either in the number of chromosomes of the standard karyotype, in their karyotype size, or between the karyotypes derived from male or female specimens of any of the species. Chromosome length decreased progressively and slightly from pair 1 to pair 24. The Ag–NOR karyotypes of E. argenteus and E. harengulus were characterized by the position of the nucleolar organizer regions next to the centromere in chromosome pair 1, whereas in E. gula and E. plumieri Ag–NORs were detected in pair 4. The other 46 chromosomes showed a light staining of the centromere with no terminal or intermediate heterochromatic blocks. All Eucinostomus species showed Ag–NORs of similar size, while Eugerres plumieri showed Ag–NORs 10–20% larger than Eucinostomus species. A combination of size and position of the Ag–NORs identified E. gula, while size alone identified E. plumieri. However, the ancestral state for size and position of Ag–NORs could not be established. There was no differential staining of the chromosomes by G-banding. The karyotype of the gerreids appears similar to the hypothetical ancestral karyotype of fish. The phylogenetic relationships among these species could not be established because of the lack of chromosome G-bands. Most likely this indicates a homogeneous distribution of GC nucleotides in the chromosomes.     

Cytological investigation of Triticale

Summary A cytological investigation of 15 different 56-chromosome Triticale and 16 Triticale with 42 chromosomes was carried out. 4 were primary Triticale and 12 were secondary Triticale. Chromosome pairing was not disturbed; 21 and 28 bivalents were found in the hexaploids and octoploids, respectively. Meiotic irregularities were established, however, in all the Triticale studied; in octoploids the frequency of the irregularities was 22–88% and in hexaploids it was 12–87%.In metaphase and anaphase asynchronous separation of chromosomes was noted. Incompatibility between wheat and rye genomes and the inactivation of single loci of rye chromosomes are suggested as the main causes of the irregularities in meiosis.Mitotic disturbances were found in all the amphidiploids. The frequency of anomalies in mitosis was considerably lower than in meiosis: in octoploids they made up 5%–11% and in hexaploids 6.2%–15.2%. In all the amphidiploids studied chimera plants were found containing pollen mother cells with different chromosome numbers. The chromosome number in the aneuploid cells varied from 8–48 in hexaploids and from 8–62 in octoploids. Octoploid Triticale had 29.4%–72.9% aneuploid pollen mother cells, while hexaploid Triticale had 5-2%–55-7%.     

Meiotic studies in Acanonicus hahni (Stål) (Coreidae,Heteroptera) I. Behaviour of univalents in desynaptic individuals

Male meiosis was studied in a population of Acanonicus hahni (Stål), and nine of the sixteen individuals analyzed showed desynapsis. The frequency of univalents varied from one to seven percent in eight of them, while in the ninth the percentage of cells with univalents was higher (12%). The univalents auto-orientate at metaphase I in the center of the ring formed by autosomal bivalents and divide equationally at anaphase I; at metaphase II they show touch-and-go pairing, and lie in the center of the ring of autosomes.A desynaptic origin of the univalents is proposed, and the arrangement of the chromosomes in the first and second metaphase plate in the normal and desynaptic individuals is compared and discussed. The meiotic characteristics of these desynaptic individuals are also compared with those described in other insects with holocentric and monocentric chromosomes. It is suggested that any achiasmatic chromosome, whether a univalent, m or sex chromosome, will induce the formation of a ring and with some or all of them lying in its centre.     

Chromosome distribution and catenation in Rhoeo spathacea var. concolor

The twelve chromosomes of Rhoeo spathacea variety concolor are arranged in a definite sequence in a ring at meiosis. Identification of all the 12 chromosomes was possible in 119 diakinesis and metaphase I cells. — Pollen viability was measured to be 36.54% by cotton blue staining procedure. Forty five of 56 metaphase I cells (80.36%) had adjacent distribution. Each of the 12 chromosomes was equally likely to be involved in adjacent distribution regardless of their sizes and heterobrachialness. Adjacent distribution occurred randomly at each arm-position in the ring regardless of the lengths of the arm-pairs. — The most frequent chromosome configuration at diakinesis and metaphase I was a chain-of-12 chromosomes (41.18%). Cells with 1 to 4 chains of chromosomes were observed. The observed frequencies of various configurations were in good agreement with the calculated frequencies. The mean number of chiasmata was 10.90 per cell and 0.908 per pair of chromosome arms. The 131 chiasma failures were distributed at random among the 12 arm-positions. Since the lengths of arm-pairs in the ring vary, the randomness may mean that chiasma formation was limited to short terminal segments on all chromosomes.     

Differential reactivity in mammalian chromosomes

Leucocyte cultures were treated with both ³H-thymidine and low temperature. Leucocyte cells were pulse labeled with ³H-thymidine for 15 to 20 minutes, and then placed in nonisotopic medium for 0, 1, 2, 3 and 4 hours respectively. Each culture was immediately treated with low temperature at 0–3° C for 24 hours. No metaphase chromosome were labeled at 0 and 1 hour after reincubation. Labeled metaphases were first observed after 2 hours of reincubation (3.9%); they increased after 3 hours (57%) and 4 hours of reincubation (39%). Labeled anaphases or telophases were also detectable in increasing proportions after 4 hours. Cell division proceeds very slowly through metaphase at low temperature. After labeling in the final 15 to 20 minutes of the S-period, one X-chromosome usually showed the late-replicating pattern. Label was found in the special segments of the X-chromosomes, X_E–a, X_L–a and X_L–b. Late-replicating regions in autosomes coincide more or less with the special segments. Differential reactivity in human chromosomes by low temperature was suggested to take place during the final part of G₂ after DNA synthesis.