Arrest in metaphase and anatomy of mitotic catastrophe: mild heat shock in two human osteosarcoma cell lines.

The exits from metaphase arrest and anatomy of mitotic catastrophe were studied in two human osteosarcoma cell lines, nontumorigenic HOS TE85 and its chemically transformed strain MNNG-HOS, applying mild genotoxic damage by heat shock at 41.8 degrees C for 24 h. Under these conditions, both cell lines doubled or tripled their mitotic index entering arrest in metaphase. On return to 37 degrees C, the arrest was either released or ended in apoptosis. The transformed strain showed a greater capacity to arrest in metaphase as well as a greater probability of developing the third pathway: to restitute this arrest in polyploid interphase. This, in turn, either entered an 'endocycle' or, following a delay, apoptosis. Thus, arrest in metaphase was a cross-point of the mitotic cycle, apoptosis, and endocycle. Mitotic catastrophe can morphologically manifest combinations of elements of these three processes.

Origin of microcells in the human sarcoma cell line HT-1080.

The aim of this study was to investigate the development of microcells in the human sarcoma cell line HT-1080 after interference with thiophosphamidum. We found that damaged interphase macrocells located at the projection of the nucleolus may form one or several microcells. The micronuclei of the microcells intensively incorporate the thymidine analogue 5-bromo-2'-deoxyuridine and strongly express argyrophilic nucleolar organiser region proteins. At an early phase of the development, the micronuclei contain fragmented DNA, but in subsequent phases, the micronuclei accumulate polymeric DNA, simultaneously with an increase in their size. After desintegration of the damaged macrocell, the microcells appear in the intercellular space. The microcells can enter mitosis and they strongly express the lung resistance protein. Electron microscopic observations suggest that coiled bodies are involved in the development of the microcells. Since the observed path of microcell formation differs from apoptotic cell fragmentation into apoptotic bodies, we propose a new term for this microcell development: sporosis. We suggest that self-renewal of the tumour stem cells is likely based on sporosis.

Apoptotic cell nuclei favour aggregation and fluorescence quenching of DNA dyes.

Apoptotic cell nuclei are known to stain hyperchromatically with absorption dyes and dimly with many DNA fluorochromes. We hypothesised that both optical phenomena have the same cause--the ability of apoptotic chromatin to aggregate cationic dyes. This hypothesis was tested using prednisolone-primed rat thymus, which is known to contain apoptotic cells. The apoptotic cells were classified as early and late, based on their morphology, in thin and semithin sections and in thymus imprints on slides. Direct reaction for DNA strand breaks (TUNEL) indicated the presence of breaks in both categories of cells, with more intense labelling in late apoptosis. The chromatin ultrastructure of early apoptotic cells initially retained the supranucleosomal order of packaging which characterises control cells, whereas the dense chromatin of late apoptotic cells possessed the degraded structure. Absorption spectra of the toluidine blue-stained early apoptotic cell chromatin revealed a metachromatic shift, indicating a change of DNA conformation and polymerisation of the dye. When the staining was performed by acridine orange (preceded by a short acid treatment), a paradoxical several-fold increase of fluorescence intensity at a several-fold dilution of the dye was found. The simultaneous reduction of the ratio of red to green components of fluorescence confirmed that the concentration-dependent fluorescence quenching was due to aggregation of the dye. The results suggest that the enhanced affinity of the chromatin of early apoptotic cells for cationic dyes is associated with conformational relaxation rather than degradation of DNA. In late apoptotic cells, the very dense packaging of degraded DNA promotes further aggregation of dyes. The results suggest alternative methods for detection and discrimination of early and late apoptotic cells.

Influence of chromatin condensation on the absorption spectra of nuclei stained with toluidine blue.

To study the influence of chromatin condensation on the absorption spectra of nuclei stained with toluidine blue, DNA staining methods--which favour or prevent dye polymerization--were applied to the imprints of rat tissues that differed greatly in the density of chromatin packing. It is stated that all factors promoting dye polymerization cause a left shift of the spectra while the factors preventing it, a right one. It was found that condensation of the chromatin can raise prerequisites that both enhance and hinder polymerization, and that the final result depends on the staining method, the manner of chromatin folding, and the density of its packing.

Anisotropic staining of apurinic acid with toluidine blue.

Using normal rat liver imprints, studies were carried out on the effects of histone extraction and the formation of aldehyde groups from deoxyribose on anisotropic toluidine blue staining of depurinized DNA after sodium bisulfite treatment. The anisotropic effect of bisulfite was found to be determined by binding of bisulfite ions to the aldehyde groups of apurinic acid which, together with free phosphate groups of DNA ensure coparallel attachment of the dye molecules. It was also shown that at pH 5.0 toluidine blue binds with both the phosphate and aldehyde groups of apurinic acid, to give anisotropic staining.

Influence of some aldehyde blocking agents on staining of depurinized DNA with cationic dyes.

Rat liver, spleen and Walker carcinosarcoma imprints were subjected to depurinizing Feulgen hydrolysis and then treated with blocking agents of aldehyde groups. Such blockators as sodium bisulfite and hydroxylamine which multiplay additionally anionic groups in DNA and intensify the reactions with cationic dyes, ensuring anisotropic staining. Hydrazine lowers the binding of carionic dyes to DNA, instead phenylhydrazine, completely blocks both aldehyde and phosphate groups. When the imprints were treated with 2.4-dinitrophenylhydrazine, aldehyde and phosphate groups of apurinic acid were blocked, and DNA staining by cationic dyes occurred only on account of nitrogroups of the blocking agents which have been used. The staining reaction of cationic dyes after the use of anionogenic blocking agents of aldehyde groups is prospective not only for revealing DNA but also for several other compounds with natural or potential aldo- and ketogroups. However the reaction with phenylhydrazine can serve as a staining without removal of DNA prior to staining as an optional procedure.