Isolated metaphase chromosomes. II. Proteins of Chinese hamster chromosomes.

The proteins on metaphase chromosomes theoretically may be distributed ubiquitously throughout the karyotype, may be present uniquely on individual chromosomes or classes of chromosomes, or may exist in any combination of the above. Separation of chromosomes according to size using sucrose velocity gradients in high capacity zonal centrifuge rotors allows sufficient fractionation of the genome to indicate the distribution of proteins within the karyotype. Flow cytometric analysis and direct microscopic analysis were used to evaluate qualitatively the types of chromosomes present in the fractions obtained. This report is the first quantitative evidence that some of the chromosomal proteins are not distributed ubiquitously on all of the chromosomes of the karyotype.     

Nucleosomes in metaphase chromosomes.

Previous studies of the structure of metaphase chromosomes have relied heavily on electron micrography and have revealed the existence of a 10-nm unit fiber that is thought to generate the native 23-30-nm fiber by higher order folding. The structural relationship of these metaphase fibers to the interphase fiber remains obscure. Recent studies on the digestion of interphase chromatin have revealed the existence of a regularly repeating subunit of DNA and histone, the nucleosome that generates the appearance of 10-nm beads connected by a short fiber of DNA seen on electron micrographs. It was therefore of interest to probe the structure of the metaphase chromosome for the presence of nucleosomal subunits. To this end metaphase chromosomes were prepared from colchicine-arrested cultures of mouse L-cells and were subjected to digestion with stayphylococcal nuclease. Comparison of the early and limit digestion products of metaphase chromosomes with those obtained from interphase nuclei indicates that although significant morphologic changes occur within the chromatin fiber during mitosis, the basic subunit structure of the chromatin fiber is retained by the mitotic chromosome.     

Insect sex chromosomes. IV DNA replication in the chromosomes of Gryllotalpa fossor

In Gryllotalpa the cell cycle duration in the hepatic caecae in vivo is about 12.5 h and of various phases are, G2 + P about 10 h, S about 2.5--3.5 h, and G1 appears negligible or absent. These estimates of the cell cycle are the only ones available in Gryllotalpidae. In the female Gryllotalpa, as in mammals, there is asynchronous DNA replication between the two euchromatic arms of the two X chromosomes. The other arm is constitutively heterochromatized and as expected is late replicating. Thus, a regulatory mechanism for dosage compensation by X chromosome inactivation appears to be operating in Gryllotalpa. This we believe, is the first cytogenetic demonstration of such a mechanism outside mammals.     

Mammalian artificial chromosomes.

A mammalian artificial chromosome would enable analysis of the cis-acting DNA sequences necessary for mammalian chromosome function and would allow large numbers of genes in a defined sequence environment to be introduced into experimental animals, agricultural livestock or human cells. Recent technical progress suggests that a route to mammalian artificial chromosome construction is now open.     

Trypsin-orcein banding in plant chromosomes.

A convenient and quick method using trypsin-orcein for banding plant chromosomes (O-banding) is suggested. The technique is directly applicable to meristematic tissues (e.g. root tips) and involves the treatment of root tips with 1-2% solution of trypsin either in buffer or in 0.5 N HCl for 5-10 minutes at 37 C or for 30-60 minutes near 0 C followed by staining with 1.5% acetic orcein: 1 N HCl (19:1). Dark staining bands are reproducible and species specific. These bands possibly represent specific DNA-protein-dye interaction.     

Construction of midget chromosomes in wheat.

To test the usefulness of breakage-fusion-bridge (BFB) cycles in generating new chromosome aberrations in bread wheat (Triticum aestivum L.) and to extend the range of aberrations available, a series of midget chromosomes was produced from the long arm of chromosome 1B. Using a reverse tandem duplication initiated chromatid type BFB cycle, the 1BL arm was broken and fused with centromeres of either chromosome 5BL or 1RS to form dicentric chromosomes. The 1R and 5B centromeres were broken by centric misdivision. Among the progenies of plants with dicentric chromosomes, two classes of monocentric chromosomes were selected: deficient chromosomes 1B and chromosomes that had 1RS or 5BL for one arm and various fragments of 1BL for the other arm. Following centric misdivision of these monocentrics, midget chromosomes 1BL were isolated: deficient and deletion telocentrics and telocentrics derived from interstitial regions of 1BL. By chance, one deficient chromosome 1BS and one deletion chromosome 1BS were identified in unrelated lines of the same wheat. Following centric misdivision of these chromosomes, two midget chromosomes covering the whole of 1BS were added to the set.     

Higher levels of organization in chromosomes.

On the basis of recent results a unified view of different aspects of the higher levels in the organization of chromatin in chromosomes is presented. Basic to these forms of organization is the arrangement of DNA in the complex with nucleosomes and recent studies suggest that at least some species of satellite DNA may maintain a fixed DNA sequence relationship to the phasing of nucleosomes. Special proteins such as the high-mobility group (HMG) proteins or other non-histone proteins could serve specific functions in the recognition of satellite DNA sequences.In the presence of histone H1 the 110 Å nucleosome fiber formed from the basic string of nucleosomes can be further condensed into a thicker 250–300 Å fiber formed by a solenoidal coiling of the 110 Å fiber with about 6–8 nucleosomes per turn and the available evidence suggests that these structures are found in mitotic chromosomes as well as other forms of inactive chromatin. A further level of coiling of the 250–300 Å solenoid has been suggested by our recent studies of disintegrated mitotic chromosomes consisting of a thin-walled tube with an outer diameter of 4000 Å referred to as the unit fiber. This structure would account for a factor of 1400 × contraction of DNA in mitotic chromosomes which in their intact state are only 5-fold more contracted. The recently described “scaffold” proteins could be responsible for this final coiling of the unit fibers in intact chromosomes.Meiotic chromosomes are generally less contracted than mitotic chromosomes. An extreme example of this are lampbrush chromosomes that apart from the axial segments which might contain some structural proteins appear to consist of naked DNA arranged in lateral loops. In the later stages of meiosis more condensed structures arise as exemplified by the synaptonemal complex during the pachytene stage in many organisms. The characteristic features of this structure are interpreted to suggest that the structure consists of lateral components containing two parallel 110 Å nucleosome fibers each representing the axial segments of two sister chromatids. From these paired regions loops protrude laterally in a manner which closely resembles the less condensed lampbrush chromosomes. The implication of this structure in the process of crossingover is discussed.Less is known about the organization of chromatin in interphase nuclei, but structures analogous to the loop-like structures in meiotic chromosomes are suggested on the basis of the isolation of supercoiled DNA loops constrained by RNA-DNA and protein-DNA interactions. The position of these loops is suggested to be fixed by specific repeated DNA sequences that could be associated with specific tenacious non-histone or HMG proteins.     

Identification of isolated metaphase chromosomes. II. A comparison with the recognizability of chromosomes in metaphase plates

The metaphase chromosomes (MC) isolated from the Chinese hamster cells were identified with the aid of differential staining (G-bands). It was shown that differences in the relative recognizability of MC in metaphase plates and after their isolation are determined by changes in composition of isolated MC, rather than by those in staining capacity of MC after their isolation. The frequencies of identified MC are constant and independent upon the type of MC preparations and relation between identified and unidentified MC in certain preparations. At allows to apply the described method for the analysis of chromosome fractionation, using changes in frequencies of identified MC as a criterion of efficiency of the fractionation method. Possible ways of increasing the recognizability level of isolated MC are discussed.     

Nature and role of accessory chromosomes in silver-gray foxes. IV. The behavior of accessory chromosomes in meiosis

Comparison of chromosome number at somatic and spermatogonial mitoses has demonstrated the increase in the number of additional chromosomes in cells of germinal tissue. This may evidence a mechanism of B-chromosomes accumulation in foxes. B-chromosomes may lag as univalents, may form bivalent associations, or occasionally form trivalents at the stage of diakinesis-metaphase I, and they may associate with macrobivalents (A-chromosome bivalents). The analysis of metaphase II has shown that the distribution of B-chromosomes in the second metaphase is random resulting in gametes with various numbers of B-chromosomes.     

Mapping replication origins in yeast chromosomes.

The replicon hypothesis, first proposed in 1963 by Jacob and Brenner, states that DNA replication is controlled at sites called origins. Replication origins have been well studied in prokaryotes. However, the study of eukaryotic chromosomal origins has lagged behind, because until recently there has been no method for reliably determining the identity and location of origins from eukaryotic chromosomes. Here, we review a technique we developed with the yeast Saccharomyces cerevisiae that allows both the mapping of replication origins and an assessment of their activity. Two-dimensional agarose gel electrophoresis and Southern hybridization with total genomic DNA are used to determine whether a particular restriction fragment acquires the branched structure diagnostic of replication initiation. The technique has been used to localize origins in yeast chromosomes and assess their initiation efficiency. In some cases, origin activation is dependent upon the surrounding context. The technique is also being applied to a variety of eukaryotic organisms.     

No detectable misrejoining in double-minute chromosomes.

Pulsed-field gel electrophoresis combined with Southern hybridization and rare-cutting restriction endonuclease digestion has been used recently to quantify misrejoining of DNA double-strand breaks (DSBs) resulting from exposure to ionizing radiation. Measurements are made 24 h after a high dose of radiation. These studies have suggested that a large fraction of DSBs are misrejoined to result in gross rearrangements. In the experiments described here, we show that elimination of broken DNA also eliminates "misrejoined" DNA. Mouse cells resistant to high levels of methotrexate by virtue of 100-fold amplification of the dyhydrofolate reductase (Dhfr) gene were treated with 50 and 100 Gy of ionizing radiation. The cells were allowed to repair the damage for 24 h. After the repair period, the cells were immobilized in agarose. Aliquots of each sample were pre-electrophoresed to remove linear DNA molecules smaller than 6 Mbp resulting from apoptosis or necrosis. The samples repairing damage from 50 or 100 Gy that did not receive the pre-electrophoresis showed high levels of label in a region of the lane that could be due to misrejoining DNA molecules. However, when the DNA from cells undergoing apoptosis or necrosis was removed from these samples, the levels of "misrejoined" DNA were reduced to levels far below those of unirradiated controls. These results suggest that other radiation-induced effects present 24 h after irradiation with 50 or 100 Gy are more significant than misrejoining for altering hybridization to regions of the lane outside the specific bands. Measurements of misrejoining using PFGE, rare-cutting restriction endonucleases, and Southern hybridization are likely to be compromised by nonspecific hybridization to broken and difficult-to-digest DNA resulting from apoptosis or necrosis.