Your search keyword '"Bojanowski K"' showing total 3 results

1. Ionic control of chromosome architecture in living and permeabilized cells.

Author

Bojanowski K and Ingber DE

Subjects

Animals, Cattle, Cells, Cultured, Chromatin chemistry, Chromatin metabolism, Chromosomes drug effects, Detergents pharmacology, Endothelium, Vascular, Magnesium Chloride pharmacology, Mitosis drug effects, Octoxynol pharmacology, Osmolar Concentration, Sodium Chloride pharmacology, Cell Membrane Permeability drug effects, Chromosomes physiology

Abstract

Studies with isolated chromatin show that higher order chromosome architecture can be regulated by ionic conditions; however, the physiological relevance of these findings remains unknown. In the present study, chromosome architecture was analyzed in situ in living and detergent-extracted cells exposed to different ionic conditions. In intact mitotic endothelial cells, chromosomes instantly unfolded as detected by phase contrast microscopy when the salt concentration in the culture medium was increased from 110 to 410 mM NaCl or from 0 to 65 mM MgCl2. When the ions were removed and the preexisting culture conditions were restored, chromosomes refolded into their original shapes and subsequently underwent mitotic division. Similar reversible effects were observed on nucleolar structure in living interphase cells as well as on mitotic chromosomes exposed to high salt after cell membranes were removed by treatment with Triton X-100. This permeabilized mitotic cell model was then used to identify proteins that remained tightly associated with chromatin during the ion-driven chromosome unfolding-refolding cycle and which therefore could be important for maintenance of chromosome structure. Under these conditions in which disassembled chromosomes retained their ability to fully recondense, more than 95% of Topoisomerase I was extracted whereas approximately 25% of Topoisomerase IIalpha and 50% of Histone H1 remained tightly associated with chromatin. These data demonstrate the sensitivity of chromosome structure to variations in ionic concentration in situ and suggest that there are at least two distinct pools of Histone H1 and Topoisomerase IIalpha associated with chromatin during mitosis, one of which may be required for chromosome compaction., (Copyright 1998 Academic Press.)

Published

1998

2. DNA topoisomerase II can drive changes in higher order chromosome architecture without enzymatically modifying DNA.

Author

Bojanowski K, Maniotis AJ, Plisov S, Larsen AK, and Ingber DE

Subjects

Animals, Catalysis, Cattle, Chromosomes metabolism, DNA Topoisomerases, Type I genetics, DNA Topoisomerases, Type I isolation & purification, Endothelium, Vascular enzymology, Enzyme Activation genetics, Recombinant Proteins isolation & purification, Recombinant Proteins pharmacology, Chromosomes enzymology, DNA metabolism, DNA Topoisomerases, Type I metabolism

Abstract

Topoisomerase II has been suggested to play a major role in chromosome organization based on its DNA decatenating activity and its ability to mediate direct binding interactions between DNA and nuclear matrix. However, this latter point remains controversial. Here we address the question of whether the chromatin binding activity of Topoisomerase II is sufficient to modify chromosome form using whole mammalian chromosomes in vitro. Intact chromosomes were microsurgically removed from living cells and disassembled by treatment with protease or heparin. When these disassembled chromosomes were incubated with recombinant human Topoisomerase II, the enzyme became incorporated into chromatin and reassembly resulted, leading to almost complete restoration of pre-existing chromosome shape and position within minutes. Chromosome reconstitution by Topoisomerase II was dose-dependent, saturable, and appeared to be controlled stoichiometrically, rather than enzymatically. Similar reassembly was observed in the absence of ATP and when a catalytically inactive thermosensitive Topoisomerase II mutant was used at the restrictive temperature. Chromosome recondensation also could be induced after the strand-passing activity of Topoisomerase II was blocked by treatment with an inhibitor of its catalytic activity, amsacrine. When a non-hydrolyzable beta,gamma-imido analog of ATP (AMP-PNP) was used to physiologically fix bound Topoisomerase II enzyme in a closed form around DNA, subsequent chromosome disassembly was prevented in the presence of high salt. These data suggest that Topoisomerase II may control higher order chromatin architecture through direct binding interactions, independently of its well-known catalytic activity.

Published

1998

3. Mechanical continuity and reversible chromosome disassembly within intact genomes removed from living cells.

Author

Maniotis AJ, Bojanowski K, and Ingber DE

Subjects

Animals, Cattle, Cell Nucleus ultrastructure, Chromosomes chemistry, Endothelium, Vascular ultrastructure, Histones physiology, Humans, Movement, Video Recording, Chromosomes ultrastructure

Abstract

Chromatin is thought to be structurally discontinuous because it is packaged into morphologically distinct chromosomes that appear physically isolated from one another in metaphase preparations used for cytogenetic studies. However, analysis of chromosome positioning and movement suggest that different chromosomes often behave as if they were physically connected in interphase as well as mitosis. To address this paradox directly, we used a microsurgical technique to physically remove nucleoplasm or chromosomes from living cells under isotonic conditions. Using this approach, we found that pulling a single nucleolus or chromosome out from interphase or mitotic cells resulted in sequential removal of the remaining nucleoli and chromosomes, interconnected by a continuous elastic thread. Enzymatic treatments of interphase nucleoplasm and chromosome chains held under tension revealed that mechanical continuity within the chromatin was mediated by elements sensitive to DNase or micrococcal nuclease, but not RNases, formamide at high temperature, or proteases. In contrast, mechanical coupling between mitotic chromosomes and the surrounding cytoplasm appeared to be mediated by gelsolin-sensitive microfilaments. Furthermore, when ion concentrations were raised and lowered, both the chromosomes and the interconnecting strands underwent multiple rounds of decondensation and recondensation. As a result of these dynamic structural alterations, the mitotic chains also became sensitive to disruption by restriction enzymes. Ion-induced chromosome decondensation could be blocked by treatment with DNA binding dyes, agents that reduce protein disulfide linkages within nuclear matrix, or an antibody directed against histones. Fully decondensed chromatin strands also could be induced to recondense into chromosomes with pre-existing size, shape, number, and position by adding anti-histone antibodies. Conversely, removal of histones by proteolysis or heparin treatment produced chromosome decondensation which could be reversed by addition of histone H1, but not histones H2b or H3. These data suggest that DNA, its associated protein scaffolds, and surrounding cytoskeletal networks function as a structurally-unified system. Mechanical coupling within the nucleoplasm may coordinate dynamic alterations in chromatin structure, guide chromosome movement, and ensure fidelity of mitosis.

Published

1997