Your search keyword '"Fittler F"' showing total 4 results

1. Neutron diffraction of chromatin in interphase nuclei and metaphase chromosomes.

Author

Ibel K, Klingholz R, Strätling WH, Bogenberger J, and Fittler F

Subjects

Animals, Cell Nucleus analysis, Chromosomes analysis, Cricetinae, Cricetulus, Female, Interphase, Liver analysis, Liver ultrastructure, Metaphase, Neutrons, Ovary analysis, Ovary ultrastructure, Rats, Cell Nucleus ultrastructure, Chromatin isolation & purification, Chromosomes ultrastructure

Abstract

We have used neutron diffraction to study chromatin structure in interphase nuclei and metaphase chromosomes as a function of decreasing ion concentration. Aliquots of a suspension of rat liver nuclei prepared in a polyamine-free buffer were washed in buffers of 1/3, 1/6 and 1/12 if the original concentration of monovalent and divalent cations (40 mM KCl; 20 mM NaCl; 1.2 mM MgCl2). After the first dilution step (1/1 to 1/3), only small changes occurred in the diffraction pattern. They can be interpreted by a loosening of the original structure, i.e. by the formation of isolated buffer-filled spaces with an overall size of the order of 35-45 nm. Drastic changes in the diffraction pattern were observed, however, when the nuclei were washed in the more diluted buffers (1/6 and 1/12). The profiles of the distances distribution functions indicate the formation of supranucleosomal particles with an overall diameter of 40-50 nm. The compact chromatin structure disassembled directly into these fundamental structural units. Structural transformations in the Chinese hamster ovary metaphase chromosomes were induced by diminishing the Ca2+ ion concentration of the buffer from originally 3.0 mM to 0.3 mM and/or by increasing the pH value of the buffer from originally 7.0 up to 8.0. The neutron diffraction patterns remained essentially unchanged during these treatments, i.e. the decondensation of the chromosomes as observed in the light microscope is not accompanied by disassembly at the ultrastructural level between 2 nm and 150 nm.

Published

1983

2. Accessibility of metaphase chromosomes from Chinese hamster ovary cells to DNase II.

Author

Fittler F, Ibel K, and Hörz W

Subjects

Animals, Buffers, Calcium pharmacology, Cations, Divalent, Cells, Cultured, Chromosomes drug effects, Cricetinae, Cricetulus, Female, Nucleosomes ultrastructure, Ovary ultrastructure, Chromosomes ultrastructure, Deoxyribonucleases pharmacology, Endodeoxyribonucleases, Endonucleases pharmacology, Metaphase, Polyamines pharmacology

Published

1981

3. A highly repetitive DNA component common to all Cervidae: its organization and chromosomal distribution during evolution.

Author

Bogenberger JM, Neitzel H, and Fittler F

Subjects

Animals, Cell Line, Male, Repetitive Sequences, Nucleic Acid, Sex Chromosomes, Species Specificity, Biological Evolution, Chromosomes analysis, DNA genetics, Deer genetics

Abstract

In recent work we have isolated and characterized a highly repetitive DNA (MMV satellite IA) from Muntiacus muntjak vaginalis, the species with the most reduced karyotype in the Cervidae family. We have now analysed the genomes of nine related species for the presence of MMV satellite IA components, and have determined their organization and chromosomal distribution. Repetitive satellite IA type DNA is present in all species of the Cervidae, and also in the bovine, but not in a species of the Tragulidae suggesting that these sequences were generated after the phylogenetic separation of Bovidae and Tragulidae. Studies on the organization of the satellite IA DNA in the various species revealed three main repeat lengths: 1400, 1000 and 807 bp. The relative proportion of satellite IA sequences present in any one of the three registers is strikingly different within the various species and can be correlated with the phylogeny of the Cervidae. The chromosomal locations of the satellite IA sequences were determined in seven species by in situ hybridization. It turned out that the chromosomal rearrangements leading to the reduction in the number of chromosomes during karyotype evolution have led to the elimination of satellite I DNA at most locations. In all tandem fusions, the satellite IA sequences located at the centromeres of the ancestral acrocentric chromosomes are lost. In contrast, during the centric fusion that generates the M. m. vaginalis X chromosome satellite IA sequences are amplified. Sequence motifs, which are known to be involved in recombinational events are present in the satellite IA and might have contributed to the unique karyotype variation in the Cervidae.

Published

1987

4. Organization and chromosomal distribution of a novel repetitive DNA component from Muntiacus muntjak vaginalis with a repeat length of more than 40 kb.

Author

Benedum UM, Neitzel H, Sperling K, Bogenberger J, and Fittler F

Subjects

Animals, Cell Line, DNA Restriction Enzymes, Deer, Male, Repetitive Sequences, Nucleic Acid, Chromosomes analysis, DNA genetics

Abstract

The organization and chromosomal distribution of the repetitive DNA component IB from Muntiacus muntjak vaginalis (MMV) was investigated. DNA fragments of component IB were cloned in cosmids and their structure analysed using restriction nucleases and blot-hybridization experiments. Two cosmids were found to be practically identical by restriction enzyme mapping. The repeat unit of component IB DNA is more than 40 kb and contains the 11 and 18 kb Bam HI fragments, which have previously been shown to cross-hybridize with MMV satellite IA. In addition, the repeat unit contains long stretches of DNA sequences which are unique to component IB. In situ hybridization experiments showed that component IB has the properties characteristic of long interspersed repetitive DNA rather than tandemly repeated satellite DNA. Consistent with this conclusion, only a minor fraction of component IB is located on the X chromosome as demonstrated by the analysis of somatic cell hybrids. This is in marked contrast to satellite IA that is specific for the X chromosome. These results have interesting implications for the evolution of the component I DNA family of the MMV genome.

Published

1986