The metaphase chromosome ultrastructure. II. Helical organization of the basic chromosome fiber as revealed by acute angle metal deposition.

The acute angle metal depositon technique, discloses a helical chromosome fiber substructure. The microdensitometric analysis of the fiber parameters shows that a fibril 152 A in diameter coils to form the basic chromosome fiber 295 A in diameter with a pitch of 247 A. These figures should be corrected because of the thickening due to metal deposition, the real dimensions would be closer to 112 A for the fibril diameter and 255 A for fiber diameter. The real pitch value is probably somewhat smaller than 247 A (approximatively 200 A) as the values were obtained by analysing slightly stretched fibers. These results support the helical model of the chromosomes fiber organization and show that, most probably, the metaphase chromosome fiber as seen in electron microscopy is the second order of helical packing.     

基于Hi-c数据的酵母染色体三维结构重构

通过染色体交互频率数据(Hi-c)来预测染色体三维空间结构是近年表观遗传研究热点。研究表明染色体三维空间结构在生物基因表达、调控等方面起到重要作用,对其进行三维重构是研究细胞代谢过程的基本途径。针对酵母Hi-c数据在不同染色体所呈现出的统计特征,拟合出每条染色体交互频率数据分布的数学模型,然后利用梯度上升迭代算法预测并重构其三维结构,并给出模型评估指标。实验结果表明,模型具有较高可重复性和预测精确度。     

Characterization of a human chromosome 22 enriched bacterial artificial chromosome sublibrary

Selection of chromosomal sublibraries from total human genomic libraries is critical for chromosome-based physical mapping approaches. We have previously reported a method of screening total human genomic library using flow sorted chromosomal DNA as a hybridization probe and selection of a human chromosome 22-enriched sublibrary from a total human bacterial artificial chromosome (BAC) library (Nucleic Acids Res 1995; 23: 1838–1839). We describe here further details of the method of construction as well as characterization of the chromosome 22-enriched sublibrary thus constructed. Nearly 40% of the BAC clones that have been mapped by fluorescence in situ hybridization (FISH) analysis were localized to chromosome 22. By screening the sublibrary using chromosome 22-specific hybridization probes, we estimated that the sublibrary represents at least 2.5 × coverage of chromosome 22. This is in good agreement with the results from FISH mapping experiments. FISH map data also indicate that chromosome 22-specific BACs in the sublibrary represent all the subregions of chromosome 22.     

Meiotic chromosome pairing in Stethophyma grossum spermatocytes studied by a surface-spreading and silver-staining technique

Spermatocytes of Stethophyma grossum were prepared for light microscope examination by a surface-spreading and silver-staining technique adapted with very little modification from a mammalian procedure. Very clear preparations of a variety of prophase I stages were obtained which revealed many details of chromosome and nuclear organisation. These observations and preliminary observations on two other grasshopper species demonstrate the ready applicability of these techniques to Orthopteran spermatocytes. A detailed study of six pachytene stage spermatocytes gave conclusive confirmation that three bivalents achieve full pairing in male meiosis of Stethophyma grossum, the other eight bivalents being partially paired at their procentric ends only.     

50 years after--examination of some circumstances around the establishment of the correct chromosome number of man

Three authors, Levan (1975, 1978), Tjio (1978) and Hultén (2002) have independently described the establishment of the correct chromosome number of man (Tjio and Levan 1956) and the background to that study. However, the three authors provide strikingly different accounts of this historical discovery. In this study I have examined the consistency between these accounts and details provided by the logbook kept at Cancer Chromosome Laboratory, University of Lund. For complementary details I have also consulted several persons that were active at the Institute of Genetics, Univ. of Lund, at the time of the discovery. Levan's (1975)Levan's (1978) accounts are both written in a modest way compared to the more self-centered narratives of Tjio and Hultén. His accounts are also consistent with all details that can be collected from the logbook. However, and most unfortunately, Levan is not explicit with respect to the dates of what might be different cytogenetic observations related to the determination of the correct chromosome number of man. The logbook leaves no room for various temporal details given by Tjio, which, if correct, might substantiate his account. Also Tjio's introduction of an alter ego into the narrative is apt to lessen the general credibility of his account. Tjio's (1978) contention of having made his human chromosome preparations at 2 a.m. on December 22nd or 23rd would be consistent with his claim that he arrived from Spain in early December 1955. His account of this crucial issue is incorrect, however, as he did not arrive at the Cancer Chromosome Laboratory until December 19. Hultén's claim of involvement becomes highly questionable in the light of her fading recollections of both the localities at the Institute of Genetics and the persons working there. Her temporal account, like that of Tjio, remains unsupported by the logbook. Examination of the logbook for temporal details relating to the establishment of the correct chromosome number of man suggests that Levan made his first preliminary 2n=46 human chromosome counts around December 20th-23rd, 1955, and that Tjio made his first conclusive preparations two-three weeks after his arrival from Spain, that is in early January 1956.     

A new chromosome fluorescence banding technique combining DAPI staining with image analysis in plants

In this study, a new chromosome fluorescence banding technique was developed in plants. The technique combined 4,6-diamidino-2-phenylindole (DAPI) staining with software analysis including three-dimensional imaging after deconvolution. Clear multiple and adjacent DAPI bands like G-bands were obtained by this technique in the tested species including Hordeum vulgare L., Oryza officinalis, Wall & Watt, Triticum aestivum L., Lilium brownii, Brown, and Vicia faba L. During mitotic metaphase, the numbers of bands for the haploid genomes of these species were about 185, 141, 309, 456 and 194, respectively. Reproducibility analysis demonstrated that banding patterns within a species were stable at the same mitotic stage and they could be used for identifying specific chromosomes and chromosome regions. The band number fluctuated: the earlier the mitotic stage, the greater the number of bands. The technique enables genes to be mapped onto specific band regions of the chromosomes by only one fluorescence in situ hybridisation (FISH) step with no chemical banding treatments. In this study, the 45S and 5S rDNAs of some tested species were located on specific band regions of specific chromosomes and they were all positioned at the interbands with the new technique. Because no chemical banding treatment was used, the banding patterns displayed by the technique should reflect the natural conformational features of chromatin. Thus it could be expected that this technique should be suitable for all eukaryotes and would have widespread utility in chromosomal structure analysis and physical mapping of genes.     

The Philadelphia chromosome in acute leukemia.

The cytogenetics, cytology and cytochemistry, clinical findings, therapeutic response and survival of patients presenting with acute leukemia and the Philadelphia chromosome (Ph1) are briefly reviewed based upon a survey of the world literature and 16 cases seen at the University of Minnesota during the last 10 years. Details regarding the 16 cases from the University of Minnesota series are presented and two appendices listing the majority of reports of Ph1 + acute leukemia are included. Comparison of adults with Ph1+ and Ph1- acute leukemia demonstrate important clinical, therapeutic and prognostic differences. In general, patients with Ph1+ acute leukemia respond less well to treatment and survive significantly shorter periods of time. Since the presence of the Philadelphia chromosome in acute leukemia has therapeutic and prognostic significance, marrow chromosome studies should be performed in adults presenting with acute leukemia, especially acute lymphocytic leukemia.     

Modelling the kinetics of chromosome exchange formation in human cells exposed to ionising radiation

A biophysical model has been applied to study the kinetics of chromosome exchange formation in human cells. Chromosomal exchange induction (for example dicentrics) by ionising radiation was modelled by means of the Monte Carlo technique. This involved energy deposition by electrons, production of chromosomal breaks (assumed to be DNA double-strand breaks) and their repair and exchange. Exchanges were assumed to result from pairwise interaction between two DNA breaks in a distance-dependent manner. The rate at which exchanges are formed was found to depend upon how the exchange to no-exchange probability ratio varied with time. The assumption that this ratio did not alter with time produced a time constant for the formation of exchanges which was exactly half that of the repair time constant. Longer time constants could not be accommodated unless the probability ratio for exchange increases with time. Different time constants for inter- and intratrack exchanges could be achieved on the basis of DNA double-strand break separation.     

Comparison of spontaneous and idoxuridine-induced micronuclei by chromosome painting

Fluorescence in situ hybridisation (FISH) technique with chromosome specific library (CSL) DNA probes for all human chromosomes were used to study about 9000 micronuclei (MN) in normal and idoxuridine (IUdR)-treated lymphocyte cultures of female and male donors. In addition, MN rates and structural chromosome aberrations were scored in Giemsa-stained chromosome spreads of these cultures. IUdR treatment (40 microg/ml) induced on the average a 12-fold increase of the MN rate. Metaphase analysis revealed no distinct increase of chromosome breaks but a preferential decondensation at chromosome 9q12 (28-79%) and to a lower extend at 1q12 (8-21%). Application of FISH technique with CSL probes to one male and one female untreated proband showed that all human chromosomes except chromosome 12 (and to a striking high frequency chromosomes 9, X and Y) occurred in spontaneous MN. In cultures containing IUdR, the chromosomal spectrum found in MN was reduced to 10 chromosomes in the male and 13 in the female proband. Eight chromosomes (2, 6, 12, 13, 14, 15, 17 and 18) did not occur in MN of both probands. On the contrary chromosomes 1 and especially 9 were found much more frequently in the MN of IUdR-treated cultures than in MN of control cultures. DAPI-staining revealed heterochromatin signals in most of the IUdR-induced MN. In an additional study, spontaneous and IUdR-induced MN were investigated in lymphocytes of another female donor using CSL probes only for chromosomes 1, 6, 9, 15, 16 and X. The results confirmed the previous finding that chromosomes 1 and 9 occur very often in MN after IUdR-treatment. The results indicate that decondensation of heterochromatic regions on chromosomes 1 and 9 caused by IUdR treatment strongly correlates with MN formation by these chromosomes.     

Centromeres: unique chromatin structures that drive chromosome segregation

Fidelity during chromosome segregation is essential to prevent aneuploidy. The proteins and chromatin at the centromere form a unique site for kinetochore attachment and allow the cell to sense and correct errors during chromosome segregation. Centromeric chromatin is characterized by distinct chromatin organization, epigenetics, centromere-associated proteins and histone variants. These include the histone H3 variant centromeric protein A (CENPA), the composition and deposition of which have been widely investigated. Studies have examined the structural and biophysical properties of the centromere and have suggested that the centromere is not simply a 'landing pad' for kinetochore formation, but has an essential role in mitosis by assembling and directing the organization of the kinetochore.     

Comparison of spontaneous and idoxuridine-induced micronuclei by chromosome painting

Fluorescence in situ hybridisation (FISH) technique with chromosome specific library (CSL) DNA probes for all human chromosomes were used to study about 9000 micronuclei (MN) in normal and idoxuridine (IUdR)-treated lymphocyte cultures of female and male donors. In addition, MN rates and structural chromosome aberrations were scored in Giemsa-stained chromosome spreads of these cultures. IUdR treatment (40 μg/ml) induced on the average a 12-fold increase of the MN rate. Metaphase analysis revealed no distinct increase of chromosome breaks but a preferential decondensation at chromosome 9q12 (28–79%) and to a lower extend at 1q12 (8–21%). Application of FISH technique with CSL probes to one male and one female untreated proband showed that all human chromosomes except chromosome 12 (and to a striking high frequency chromosomes 9, X and Y) occurred in spontaneous MN. In cultures containing IUdR, the chromosomal spectrum found in MN was reduced to 10 chromosomes in the male and 13 in the female proband. Eight chromosomes (2, 6, 12, 13, 14, 15, 17 and 18) did not occur in MN of both probands. On the contrary chromosomes 1 and especially 9 were found much more frequently in the MN of IUdR-treated cultures than in MN of control cultures. DAPI-staining revealed heterochromatin signals in most of the IUdR-induced MN. In an additional study, spontaneous and IUdR-induced MN were investigated in lymphocytes of another female donor using CSL probes only for chromosomes 1, 6, 9, 15, 16 and X. The results confirmed the previous finding that chromosomes 1 and 9 occur very often in MN after IUdR-treatment. The results indicate that decondensation of heterochromatic regions on chromosomes 1 and 9 caused by IUdR treatment strongly correlates with MN formation by these chromosomes.     

Acute lymphocytic and myelomonocytic leukemia associated with low platelet counts and a 21q- marker chromosome

Summary A terminal deletion of the long arm of one chromosome 21 at band q21 was found in two patients with acute leukemia and a low platelet count: one case of acute myelomonocytic leukemia and one case of acute lymphocytic leukemia. The segment deleted from chromosome 21 could not be found translocated to any other chromosome of the complement. The results indicate that the 21q- marker chromosome may be due to a true deletion and that the marker is not specific for primary thrombocythemia or other myeloproliferative disorders associated with thrombocytosis.     

Molecular cloning of zebra finch W chromosome repetitive sequences: evolution of the avian W chromosome

The zebra finch (Taeniopygia guttata) has a large Z chromosome and highly condensed W chromosome. We used the random amplified polymorphic DNA (RAPD) polymerase chain reaction (PCR) technique to isolate female-specific sequences ZBM1 and ZBM2. Southern blot hybridization to male and female zebra finch genomic DNA suggested that these sequences were located on the W chromosome, although homologous sequences appeared to be autosomal or Z-linked. Fluorescent in situ hybridization (FISH) using bacterial artificial chromosome (BAC) clones corresponding to ZBM sequences showed hybridization to the whole W chromosome, suggesting that the BACs encode sequences that are repeated across the entire W chromosome. Based on the sequencing of a ZBM repetitive sequence and Z chromosome derived BAC clones, we demonstrate a random distribution of repeat sequences that are specific to the W chromosome or encoded by both Z and W. The positions of ZW-common repeat sequences mapped to a noncoding region of a Z chromosome BAC clone containing the CHD1Z gene. The apparent lineage-specificity of W chromosome repeat sequences in passerines and galliform birds suggest that the W chromosome had not differentiated well from the Z at the time of divergence of these lineages. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Flexible chromosome painting based on multiplex PCR of oligonucleotides and its application for comparative chromosome analyses in Cucumis

Chromosome painting is a powerful technique for chromosome and genome studies. We developed a flexible chromosome painting technique based on multiplex PCR of a synthetic oligonucleotide (oligo) library in cucumber (Cucumis sativus L., 2n = 14). Each oligo in the library was associated with a universal as well as nested specific primers for amplification, which allow the generation of different probes from the same oligo library. We were also able to generate double‐stranded labelled oligos, which produced much stronger signals than single‐stranded labelled oligos, by amplification using fluorophore‐conjugated primer pairs. Oligos covering cucumber chromosome 1 (Chr1) and chromosome 4 (Chr4) consisting of eight segments were synthesized in one library. Different oligo probes generated from the library painted the corresponding chromosomes/segments unambiguously, especially on pachytene chromosomes. This technique was then applied to study the homoeologous relationships among cucumber, C. hystrix and C. melo chromosomes based on cross‐species chromosome painting using Chr4 probes. We demonstrated that the probe was feasible to detect interspecies chromosome homoeologous relationships and chromosomal rearrangement events. Based on its advantages and great convenience, we anticipate that this flexible oligo‐painting technique has great potential for the studies of the structure, organization, and evolution of chromosomes in any species with a sequenced genome.     

Sex chromosome positions in human interphase nuclei as studied by in situ hybridization with chromosome specific DNA probes

Summary Two cloned repetitive DNA probes, pXBR and CY1, which bind preferentially to specific regions of the human X and Y chromosome, respectively, were used to study the distribution of the sex chromosomes in human lymphocyte nuclei by in situ hybridization experiments. Our data indicate a large variability of the distances between the sex chromosomes in male and female interphase nuclei. However, the mean distance observed between the X and Y chromosome was significantly smaller than the mean distance observed between the two X-chromosomes. The distribution of distances determined experimentally is compared with three model distributions of distances, and the question of a non-random distribution of sex chromosomes is discussed. Mathematical details of these model distributions are provided in an Appendix to this paper. In the case of a human translocation chromosome (XqterXp22.2::Yq11Y qter) contained in the Chinese hamster x human hybrid cell line 445 x 393, the binding sites of pXBR and CY1 were found close to each other in most interphase nuclei. These data demonstrate the potential use of chromosome-specific repetitive DNA probes to study the problem of interphase chromosome topography.     

Stability, structure and complexity of yeast chromosome III.

The complete sequence of yeast chromosome III provides a model for studies relating DNA sequence and structure at different levels of organisation in eukaryotic chromosomes. DNA helical stability, intrinsic curvature and sequence complexity have been calculated for the complete chromosome. These features are compartmentalised at different levels of organisation. Compartmentalisation of thermal stability is observed from the level delineating coding/non-coding sequences, to higher levels of organisation which correspond to regions varying in G + C content. The three-dimensional path reveals a symmetrical structure for the chromosome, with a densely packed central region and more diffuse and linear subtelomeric regions. This interspersion of regions of high and low curvature is reflected at lower levels of organisation. Complexity of n-tuplets (n = 1 to 6) also reveals compartmentalisation of the chromosome at different levels of organisation, in many cases corresponding to the structural features. DNA stability, conformation and complexity delineate telomeres, centromere, autonomous replication sequences (ARS), transposition hotspots, recombination hotspots and the mating-type loci.     

Condensin: crafting the chromosome landscape

The successful transmission of complete genomes from mother to daughter cells during cell divisions requires the structural re-organization of chromosomes into individualized and compact structures that can be segregated by mitotic spindle microtubules. Multi-subunit protein complexes named condensins play a central part in this chromosome condensation process, but the mechanisms behind their actions are still poorly understood. An increasing body of evidence suggests that, in addition to their role in shaping mitotic chromosomes, condensin complexes have also important functions in directing the three-dimensional arrangement of chromatin fibers within the interphase nucleus. To fulfill their different functions in genome organization, the activity of condensin complexes and their localization on chromosomes need to be strictly controlled. In this review article, we outline the regulation of condensin function by phosphorylation and other posttranslational modifications at different stages of the cell cycle. We furthermore discuss how these regulatory mechanisms are used to control condensin binding to specific chromosome domains and present a comprehensive overview of condensin’s interaction partners in these processes.     

The repair of bleomycin-induced DNA damage and its relationship to chromosome aberration repair.

Previous studies using the technique of premature chromosome condensation indicated that nearly one-half of the bleomycin-induced chromatid breaks and gaps in CHO cells could be repaired within 1 h (repair starting at 30 min) after treatment. Cycloheximide and streptovitacin A (but not hydroxyurea or hycanthone) inhibited chromosome repair. The purpose of this study was to measure the kinetics of DNA repair after bleomycin treatment using the alkaline elution technique and to determine whether various inhibitors could block this repair. After bleomycin treatment, the major proportion of the repair of DNA damage occurred within 15 min, with significant repair evident by 2 min. This fast repair component was inhibited by 0.2% EDTA. A slower repair component was observed to occur up to 60 min after bleomycin treatment. None of the inhibitors tested were found to have a significant effect on the repair of bleomycin damage at the DNA level. Since chromosome breaks were observed not to begin repair until after 30 min while over 50% of the DNA was repaired by 15 min, these results suggest that the DNA lesions that are repaired quickly are not important in the formation of chromosome aberrations. Further, since cycloheximide and streptovitacin A blocked chromosome repair but had little measurable effect on DNA repair, these results suggest that the DNA lesions responsible for chromosome damage represent only a small proportion of the total DNA lesions produced by bleomycin.