On the continuity of chromosomal subunits: an analysis of induced ring chromosomes in Vicia faba

The proposition that subunits of a chromatid are continuous in a directional sense has been tested by observing the behaviour of induced ring chromosomes in Vicia faba. On the simplest hypothesis, that the subunits are the uninterrupted complementary strands of the DNA molecule, the polarity of rejoining should result in free separation of rings following replication in successive cell cycles. Centric and acentric ring chromosomes were separately assessed in both diploid and colchicine-accumulated tetraploid metaphase cells of primary root tips. Contrary to expectation large numbers of single and interlocked rings were observed in both cell cycles. Spontaneous sister chromatid exchanges and other breakage-reunion events can produce the configurations seen; with the postulated level of sister chromatid exchange equating that determined autoradiographically in rod chromosomes of V. faba. Unless the replication of ring chromosomes produces conditions unusual in rod chromosome replication, spontaneous breakage is probably common in replicating or post replication Vicia chromosomes. — A fundamental difference exists between the behaviour of centric and acentric ring chromosomes. Acentric ring chromosomes behave as if the chromatid arm were one DNA molecule, or a number of DNA molecules with identical directional sense. However, centric ring chromosomes behave as if there were a difference at the centromere in at least one (probably the metacentric) chromosome of the Vicia complement. That is, the two duplication-segregation subunits which extend the length of the chromosome, may contain a change in polarity at the centromere.     

Analyse des échanges de chromatides dans les cellules somatiques humaines

A new technique (BUdR treatment followed by acridine orange staining) allowing a differentiation of sister chromatids is described. A statistical analysis of 91 human karyotypes gives an estimate of the frequency of exchanges. The mean of sister chromatid exchanges is 27,3 and the minimum number is 11 per cell. — The frequency of these exchanges is proportional to the relative length of each chromosome, and the accumulation of several exchanges in some segments evokes the possibility of a negative interference. — The analysis of endomitoses treated with BUdR during at least two generations is not in disagreement with the model of semi-conservative replication of chromosomal DNA, but the modifications of the chromatids may result from a completely different process. — The frequency of endomitoses is increased by the treatment. These endomitoses allow a very precise analysis of the evolution of the sister chromatid exchanges, during two successive cellular generations.

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Travail de l'E.R.A. N 47 du C.N.R.S. et C.E.A. Contrat N 293.     

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.     

In vivo BrdU-33258 Hoechst analysis of DNA replication kinetics and sister chromatid exchange formation in mouse somatic and meiotic cells

BrdU (5-bromodeoxyuridine)-33258 Hoechst methods have been adapted for in vivo analyses of replication kinetics, sister chromatid differentiation and sister chromatid exchange (SCE) formation in mice. Sufficient in vivo BrdU substitution for cytological detection was effected with multiple intraperitoneal injections of the analogue. The combination of centromere staining asymmetry and sister chromatid differentiation at metaphase permits unambiguous determination of the number of replications in BrdU and dT (deoxythymidine) undergone by individual cells. Late-replicating regions in marrow and spermatogonial chromosomes are highlighted by bright fluorescence after sequential incorporation of BrdU followed by dT during a single DNA synthesis period. SCEs are analyzed in marrow and spermatogonial metaphases after successive complete cycles of BrdU and dT incorporation. Significant induction of SCE was observed with both mitomycin C and cyclophosphamide; the latter drug requires host-mediated activation to be effective. In meiotic metaphase cells harvested two weeks after BrdU incorporation, satellite DNA asymmetry, sister chromatid differentiation and SCE could be detected in a few chromosomes, most frequently the X and the Y.     

Fluorometrical detection of thymine base differences in complementary strands of satellite DNA in human metaphase chromosomes.

Using the fluorochrome "Hoechst 33258", intensity of fluorescence was found to differ distinctly between the sister chromatids in the paracentric regions of chromosomes 1, 16, and 19, after one round of replication in medium containing BUdR. Thus the effect of fluorescence asymmetry is not limited to the part of the Y chromosomes that fluoresces intensely with quinacrine; it can also be determined in the weakly Q-fluorescent pericentric regions of chromosomes, which are known to be the sites where highly reiterated sequences of satellite DNA are located. However, an exception is the paracentric region of chromosome 9 which does not show the effect of lateral asymmetry. The difference of fluorescence intensity in the heterochromatic regions of the sister chromatids of human chromosome 1 is measured by densitometric tracement along the long axes of chromosomes; this is obtained from two individuals with an "uncoiler" heterchomatic block (type III) having a relative intensity of 1:1.93 in an average of the total measured blocks. This corresponds to the uneven distribution of thymine base of 22.8 and 43.2 in the two strands of the DNA double hexlix. A chromatid exchange rate of 9 in 100 metaphases per cell cycle was found within the uncoiler region of chromosome 1.     

草鱼染色体的包装（间期—中期）

以草鱼ＺＣ７９０１细胞株为材料,观察鱼类细胞从间期染色质到中期染色体的包装过程。主要通过（１）分裂期与间期细胞融合,诱导染色体早熟凝集;（２）染色体“伸长”处理;（３）培养细胞的低渗处理;（４）染色质辅展等方法,制作染色体标本,进行扫描和透射电镜观察。观察表明,鱼类染色质的基本结构与哺乳类细胞相同,也是直径约１０ｎｍ的核丝。染色体的色装有两种形式：一种是多级螺旋化形成直径约３００ｎｍ的染色单体,     

A study of heterochromatin in Drosophila nasuta by the 5-bromodeoxyuridine-giemsa staining technique

Larval brain ganglia of Drosophila nasuta were cultured in vitro in the presence of 5-bromodeoxyuridine for 1 or 5 h at 24° C and the air-dried chromosome preparations stained by the Hoechst 33258-Giemsa technique to reveal bromodeoxyuridine induced sister chromatid differentiation. In 1 h as well as 5 h preparations, 10–15% of well spread metaphase plates show a sister chromatid differentiation in only C-band heterochromatin regions of different chromosomes. We infer that this sister chromatid differentiation in all heterochromatic regions is seen after bromodeoxyuridine incorporation for only one replication cycle and is related to the presence of asymmetric A-T rich satellite sequences in all the C-band regions of D. nasuta karyotype.     

Differential giemsa staining of sister chromatids and the study of sister chromatid exchanges without autoradiography

Chinese hamster ovary cells grown for two rounds of DNA replication in the presence of BrdUrd contain sister chromatids that fluoresce differentially when stained with Hoechst 33258. If such fluorescent treatments are followed by incubation in 2 X SSC or water at 62° C and staining in 3% Giemsa, the chromosomes now contain one dark (unifilarly substituted) chromatid and one light (bifilarly substituted) chromatid, i.e. are harlequinized. These preparations do not fade and can be studied without resorting to fluorescence microscopy. Sister chromatid exchanges (SCE's) are seen with great clarity and resolution; and all the chromosomes in a cell can be scored, which is contrary to the usual experience with autoradiography. It was found that a) the yield of SCE's is dependent upon the concentration of BrdUrd in which the cells are grown and that the maximum number of SCE's that can occur spontaneously is 0.15 per chromosome per division cycle, b) the yield of SCE's doubles if the cells are exposed to visible light that can cause the photolysis of BrdUrd-containing DNA, and c) chromosomes that appear isolabelled in autoradiographic preparations come from observable multiple exchanges and are not the result of the segregation of DNA from a binemic chromosome. Furthermore, the staining patterns obtained in endoreduplicated cells clearly confirm that the polynucleotide strands of the DNA segregate into sister chromatids as though the newly synthesized strands were laid on the outside of the replicating double helix.     

Differential gene activity visualized on sister chromatids after replication in the presence of 5-azacytidine

Mitotic chromosomes with sister chromatids bearing differentially active ribosomal gene clusters were recovered from human lymphocytes exposed to 5-azacytidine. The hypothesis was that the differential activity was determined by the hypomethylation of one of the two sister chromatids. The verification was carried out by labeling the 5-azacytidine-substituted chromatid with BUdR, and then checking the location of active clusters by specific staining techniques. Data obtained confirmed that the chromatid bearing the active cluster was indeed the 5-azacytidine-substituted one.     

In vivo BUdR labeling of mammalian chromosomes

A technique is described for labeling mammalian chromosomes in vivo with BUdR. Rats and mice are given BUdR by tail vein infusion over a 24-h period at a concentration of 25 μg/g wt/h. Metaphase cells that have gone through two or three cycles of DNA synthesis reveal characteristic differential chromatid fluorescence after staining with Hoechst dye. Sister chromatid exchanges can then be easily detected in these cells.     

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.     

The distribution of SCEs within and between the genomes of an interspecific hybrid

The distribution of sister chromatid exchanges has been examined in the chromosomes of a hybrid male wallaby (Macropus rufogriseus x Wallabia bicolor ), and in the X chromosomes of M. parryi and M. rufus. Comparisons were made of SCE frequency between the two genomes of the hybrid, only one of which has an appreciable amount of constitutive heterochromatin, and between the euchromatic and heterochromatic regions of the M. rufogriseus genome. The frequency of SCEs is closely correlated with the DNA content of the individual chromosomes. The distribution of the SCEs between the euchromatin and heterochromatin in the M. rufogriseus genome showed a deficiency of SCEs observed in the heterochromatin compared with the euchromatin. —A substantial excess of SCEs occurred at the nucleolar organiser region of the M. rufogriseus X chromosome. This excess was absent from the nucleolar organiser region of the X chromosome of the two other macropodine species studied and is accounted for by the presence of an adjacent euchromatin-heterochromatin junction.     

Relationship between relative dry mass and average band width in regions of polytene chromosomes of Drosophila

Whole-mounted polytene chromosomes from Drosophila melanogaster were prepared for high-voltage electron microscopy. Relative dry mass of chromosome regions was estimated by densitometry of electron microscopic negatives. Comparison of dry mass of regions of the male X chromosome with that of regions of associated autosomes established that dry mass values are proportional to DNA content. Relative dry mass values of regions of polytene chromosomes from salivary glands, fat body, and malpighian tubules were correlated with the average diameter of bands in these regions: as mass doubled, band width increased by a factor of approximately 2. To provide a standard for estimating absolute levels of polyteny, band widths were measured for chromosomes representing one major polytene class, 256n. These chromosomes were observed to have an average band width of 0.9 m — These observations provide limits to models of chromatin organization in bands. For each chromatid, this area can accommodate up to five chromatin fibers of 250 Å diameter. This value may represent the extent of folding of a chromatin fiber in an average band. Alternatively, a chromatin fiber of higher-order structure could have a maximum diameter of 560 Å in an average band.     

The UV sensitivity of the bromodeoxyuridine-substituted chromosomes in the Chinese hamster

Chinese hamster cells with chromosomes differently substituted for BUdR (TT-TT, TT-TB, TB-TB, TB-BB, where T is thymidine containing chromatid and B is BUdR substituted chromatid) were exposed to UV-light in phase G2 and chromosome aberrations (mainly chromatid breaks) were analysed. Breaks frequency per chromosome was proportional to BUdR content. No breaks were found in TT-TT chromosomes. The frequency of breaks per TB chromatid was similar with TT-TB and TB-BB chromosomes. In TB-BB chromosomes, however, virtually no breaks occurred in TB chromatids whereas in BB chromatids, their frequency was much higher than was expected.     

Late replicating bands of human chromosomes demonstrated by fluorochrome and Giemsa staining.

The addition of thymidine (TdR) to cells growing in a medium containing 5-bromodeoxyuridine (BUdR) at the end of the first replication cycle results in the incorporation of TdR into the late replicating DNA regions. These sites can be visualized by staining the metaphase chromosomes with the fluorescent dye "33258 Hoechst" or a "33258 Hoechst" Giemsa procedure. A sequence of late replication patterns has been established in metaphase chromosomes of cultured human peripheral lymphocytes. The patterns are in agreement with those obtained by the standard autoradiographic procedures, but are more accurate. As is known from autoradiography, late replicating bands are in the position of G or Q bands. The "33258 Hoechst" Giemsa staining procedure of chromosomes which have replicated in the presence of BUdR first and in TdR for the last 2 hrs of the S phase is preferable to the currently used Giemsa banding techniques: the method yields very well banded metaphases in all preparations examined, as the chromosome structure is not disrupted by the pretreatment. The bands are very distinct, even in the "difficult" chromosomes (e.g. No. 4, 5, 8 and X). In female cells the late replicating X chromosome can be identified by its size and staining pattern. In addition to the replication asynchrony, the sequence of replication within both X chromosomes in female cells is not absolutely identical. The phenomenon of a phase difference in replication between the homologues is not a peculiarity of the X chromosome, but can be found in all autosomes as well as in homologous positions on the chromatids of individual chromosomes.     

Sister Chromatid Cohesion

During S phase, not only does DNA have to be replicated, but also newly synthesized DNA molecules have to be connected with each other. This sister chromatid cohesion is essential for the biorientation of chromosomes on the mitotic or meiotic spindle, and is thus an essential prerequisite for chromosome segregation. Cohesion is mediated by cohesin complexes that are thought to embrace sister chromatids as large rings. Cohesin binds to DNA dynamically before DNA replication and is converted into a stably DNA-bound form during replication. This conversion requires acetylation of cohesin, which in vertebrates leads to recruitment of sororin. Sororin antagonizes Wapl, a protein that is able to release cohesin from DNA, presumably by opening the cohesin ring. Inhibition of Wapl by sororin therefore “locks” cohesin rings on DNA and allows them to maintain cohesion for long periods of time in mammalian oocytes, possibly for months or even years.DNA replication during the synthesis (S) phase generates identical DNA molecules, which, in their chromatinized form, are called sister chromatids. The pairs of sister chromatids remain united as part of one chromosome during the subsequent gap (G₂) phase and during early mitosis, in prophase, prometaphase, and metaphase. During these stages of mitosis chromosomes condense, in most eukaryotes the nuclear envelope breaks down, and in all species chromosomes are ultimately attached to both poles of the mitotic spindle. Only once this biorientation has been achieved for all chromosomes, the sister chromatids are separated from each other in anaphase and transported toward opposite spindle poles of the mother cell, enabling its subsequent division into two genetically identical daughter cells.This series of events critically depends on the fact that sister chromatids remain physically connected with each other from S phase until metaphase. This physical connection, called sister chromatid cohesion, opposes the pulling forces that are generated by microtubules that attach to kinetochores and thereby enables the biorientation of chromosomes on the mitotic spindle (Tanaka et al. 2000b). Without cohesion, sister chromatids could therefore not be segregated symmetrically between the forming daughter cells, resulting in aneuploidy. For the same reasons, cohesion is essential for chromosome segregation in meiosis I and meiosis II. Cohesion defects in human oocytes can lead to aneuploidy, which is thought to be the major cause of spontaneous abortion, because only a few types of aneuploidy are compatible with viability, such as trisomy 21 (Down syndrome), trisomy 18 (Edwards syndrome), and trisomy 13 (Patau syndrome) (Hunt and Hassold 2010). Studying the mechanisms of cohesion is therefore essential for understanding how the genome is passed properly from one cell generation to the next.In addition, sister chromatid cohesion facilitates the repair of DNA double-strand breaks in cells that have replicated their DNA, where such breaks can be repaired by a homologous recombination mechanism that uses the undamaged sister chromatid as a template (for review, see Watrin et al. 2006). Furthermore, mutations in the proteins that are required for sister chromatid cohesion can cause defects in chromatin structure and gene regulation, and can in rare cases lead to congenital developmental disorders, called Cornelia de Lange syndrome, Roberts/SC Phocomelia syndrome, and Warsaw Breakage syndrome (for review, see Mannini et al. 2010).     

Actinomycin D effects on mitosis and chromosomes: sticky chromatids and localized lesions

When Indian muntjac and Chinese hamster cells in culture were treated with Actinomycin D (1 g/ml) for 1–2 hours, the sister chromatids, especially the distal segments, appeared to have difficulty separating in anaphase. The separated proximal segments progressively became stretched. The nucleolus organizer regions seemed to be most susceptible to stretching, and breaks in these regions were frequently observed. Electron microscopic observations showed that the sticky chromatids (and less frequently sticky chromosomes) contain connecting submicroscopic chromosome strands. When the treated cells were allowed to grow in a drug-free medium for several days, a high frequency of endoreduplicated mitotic figures was found. Chromosome and chromatid breaks and other aberrations were common, mainly localized at G band negative areas particularly nucleolus organizer regions.     

Replication pattern of the X and Y chromosomes in partially synchronized human lymphocyte cultures

The replication pattern of the X and Y chromosomes at the beginning of the synthetic phase was studied in human lymphocyte cultures partially synchronized by the addition of 5-fluoro-2-deoxyuridine (FUdR). The data were evaluated statistically by an analysis of the distribution of silver grain counts over the X and Y chromosomes. —In cells from normal females, one of the X chromosomes began replication later than any other chromosomes of the complement. The short arm of the late replicating X chromosome started replication earlier than the long arm. The telomeric region of the short arm was a preferential site of DNA synthesis at the beginning of replication. —In partially synchronized lymphocyte cultures from a patient with the XXY syndrome, the Y chromosome started replication together with the late replicating X chromosome. The Y chromosome most frequently replicated synchronously with the short arm of the X. The centromeric region of the Y chromosome initiated synthesis before the telomeric region and appeared to replicate synchronously with the telomeric region of the short arm of the X. These findings are discussed with reference to the pairing of the X and Y chromosomes at meiosis.Supported in part by the National Institute of Health Research Grant HD-01979 and National Foundation Birth Defects Research Grant CRCS-40. Dr. Knight was a predoctoral fellow under National Institute of Health Training Program HD-00049-09.     

Automatic measurement of sister chromatid exchange frequency.

An automatic system for detecting and counting sister chromatid exchanges in human chromosomes has been developed. Metaphase chromosomes from lymphocytes which had incorporated 5-bromodeoxyuridine for two replication cycles were treated with the dye 33258 Hoechst and photodegraded so that the sister chromatids exhibited differential Giemsa staining. A computer-controlled television-microscope system was used to acquire digitized metaphase spread images by direct scanning of microscope slides. Individual objects in the images were identified by a thresholding procedure. The probability that each object was a single, separate chromosome was estimated from size and shape measurements. An analysis of the spatial relationships of the dark-chromatid regions of each object yielded a set of possible exchange locations and estimated probabilities that such locations corresponded to sister chromatid exchanges. A normalized estimate of the sister chromatid exchange frequency was obtained by summing the joint probabilities that a location contained an exchange within a single, separate chromosome over the set of chromosomes from one or more cells and dividing by the expected value of the total chromosome area analyzed. Comparison with manual scoring of exchanges showed satisfactory agreement up to levels of approximately 30 sister chromatid exchanges/cell, or slightly more than twice control levels. The processing time for this automated sister chromatid exchange detection system was comparable to that of manual scoring.     

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.