DNA loop domain organization in nucleoids from cells of different types.

The loop domain organization of chromatin plays an important role in transcription regulation and thus may be assumed to vary in cells of different types. We investigated the kinetics of DNA loop migration during single cell gel electrophoresis (the comet assay) for nucleoids obtained from human lymphocytes, lymphoblasts and glioblastoma T98G cells. The results confirm our previous observation that there are three parts of DNA in nucleoids: DNA on the nucleoid surface, loops up to ∼150 kb inside the nucleoid, and larger loops that cannot migrate. However, the relative amounts of the three parts were found to be very different for different cell types. The distributions of the loop length up to 150 kb were shown to be exponential, with the distribution parameter, the loop density, to be dependent on the cell type.

Single nucleus versus single-cell gel electrophoresis: kinetics of DNA track formation.

Single-cell gel electrophoresis, or the comet assay, is usually performed with nucleoids prepared after a lysis of either whole cells (more often) or isolated cell nuclei (rarely). Electrophoretic properties of the second type of nucleoids have never been investigated carefully. We measured the kinetics of the DNA exit from nuclei-derived nucleoids in comparison with cell-derived nucleoids. The results show that general organization of the nuclei-derived nucleoids is not changed very much in comparison with nucleoids commonly obtained from whole cells. At the same time, in contrast to the cell-derived nucleoids, for which the exit is stepwise and cooperative, the DNA exit from the nuclei-derived nucleoids can be described by a simple monomolecular kinetics. This difference is probably due to agarose penetration into nuclei (but not into cells) before polymerization of the agarose gel. We suggest that single-nucleus gel electrophoresis may be a way for the comet assay standardization.

DNA loop domain organization as revealed by single-cell gel electrophoresis.

At higher order levels chromatin is organized into loops. This looping, which plays an important role in transcription regulation and other processes, remains poorly understood. We investigated the kinetics of DNA loop migration during single cell gel electrophoresis (the comet assay). The migration of a part of the loops was shown to be reversible after switching off electrophoresis and to be sensitive to intercalation-induced changes in supercoiling. Another group of the loops migrates rapidly, the rate being insensitive to the supercoiling level. The largest part of the loops cannot migrate at all, presumably because of their large size. The loop ends can be detached in the presence of high concentrations of intercalators or protein denaturants, thus increasing the fraction of DNA that cannot migrate in the gel. The distribution of the loop length up to 100kilobases appears to be consistent with the fractal globule organization.