Adaptive response to DNA and chromosomal damage induced by X-rays in human blood lymphocytes.

Nucleoid sedimentation, single-cell gel electrophoresis (comet assay) and premature chromosome condensation (PCC) technique were utilized to estimate the involvement of DNA strand breaks and chromosomal damage in radio-adaptive response of stimulated human lymphocytes. Conditioning of cells with 0.02 Gy X-rays rendered them more resistant to single- and double-strand DNA breaks produced by 1 Gy challenging treatment as revealed by the sedimentation behaviour of the nucleoids and the comet assay. Nucleoid sedimentation also demonstrated that adaptive reaction towards X-ray-induced DNA damage is favoured in the presence of oxygen. A concomitant decrease in the amount of interphase chromosomal breaks visualized by PCC under the same experimental conditions was observed. Data indicate that adaptation of human lymphocytes to X-rays is tightly linked to the reduced susceptibility towards generation of DNA and chromosomal breaks. It is proposed that the very persistence of DNA strand discontinuities might serve as a triggering signal for the adaptation of human lymphocytes against ionizing radiation exposure.

Pairing of heterochromatin in response to cellular stress.

We previously reported that exposure of human cells to DNA-damaging agents (X-rays and mitomycin C (MMC)) induces pairing of the homologous paracentromeric heterochromatin of chromosome 9 (9q12-13). Here, we show that UV irradiation and also heat shock treatment of human cells lead to similar effects. Since the various agents induce very different types and frequencies of damage to cellular constituents, the data suggest a general stress response as the underlying mechanism. Moreover, local UV irradiation experiments revealed that pairing of heterochromatin is an event that can be triggered without induction of DNA damage in the heterochromatic sequences. The repair deficient xeroderma pigmentosum cells (group F) previously shown to fail pairing after MMC displayed elevated pairing after heat shock treatment but not after UV exposure. Taken together, the present results indicate that pairing of heterochromatin following exposure to DNA-damaging agents is initiated by a general stress response and that the sensing of stress or the maintenance of the paired status of the heterochromatin might be dependent on DNA repair.

Mitomycin C-induced pairing of heterochromatin reflects initiation of DNA repair and chromatid exchange formation.

Chromatid interchanges induced by the DNA cross-linking agent mitomycin C (MMC) are over-represented in human chromosomes containing large heterochromatic regions. We found that nearly all exchange breakpoints of chromosome 9 are located within the paracentromeric heterochromatin and over 70% of exchanges involving chromosome 9 are between its homologues. We provide evidence that the required pairing of chromosome 9 heterochromatic regions occurs in G(0)/G(1) and S-phase cells as a result of an active cellular process initiated upon MMC treatment. By contrast, no pairing was observed for a euchromatic paracentromeric region of the equal-sized chromosome 8. The MMC-induced pairing of chromosome 9 heterochromatin is observed in a subset of cells; its percentage closely mimics the frequency of homologous interchanges found at metaphase. Moreover, the absence of pairing in cells derived from XPF patients correlates with an altered spectrum of MMC-induced exchanges. Together, the data suggest that the heterochromatin-specific pairing following MMC treatment reflects the initiation of DNA cross-link repair and the formation of exchanges.

Ionizing radiation-induced instant pairing of heterochromatin of homologous chromosomes in human cells.

Using fluorescence in situ hybridization with human band-specific DNA probes we examined the effect of ionizing radiation on the intra-nuclear localization of the heterochromatic region 9q12-->q13 and the euchromatic region 8p11.2 of similar sized chromosomes 9 and 8 respectively in confluent (G1) primary human fibroblasts. Microscopic analysis of the interphase nuclei revealed colocalization of the homologous heterochromatic regions from chromosome 9 in a proportion of cells directly after exposure to 4 Gy X-rays. The percentage of cells with paired chromosomes 9 gradually decreased to control levels during a period of one hour. No significant changes in localization were observed for chromosome 8. Using 2-D image analysis, radial and inter-homologue distances were measured for both chromosome bands. In unexposed cells, a random distribution of the chromosomes over the interphase nucleus was found. Directly after irradiation, the average inter-homologue distance decreased for chromosome 9 without alterations in radial distribution. The percentage of cells with inter-homologue distance <3 micro m increased from 11% in control cells to 25% in irradiated cells. In contrast, irradiation did not result in significant changes in the inter-homologue distance for chromosome 8. Colocalization of the heterochromatic regions of homologous chromosomes 9 was not observed in cells irradiated on ice. This observation, together with the time dependency of the colocalization, suggests an underlying active cellular process. The biological relevance of the observed homologous pairing remains unclear. It might be related to a homology dependent repair process of ionizing radiation induced DNA damage that is specific for heterochromatin. However, also other more general cellular responses to radiation-induced stress or change in chromatin organization might be responsible for the observed pairing of heterochromatic regions.

Separation of neonatal rat ventricular myocytes and non-myocytes by centrifugal elutriation.

The preparation of pure cardiac myocyte cultures from neonatal rats is hampered by the presence of non-myocytes, which can proliferate during culturing, thereby causing a progressive decrease in the proportion of myocytes. In order to obtain myocyte cell suspensions of high purity, a method based on centrifugal elutriation was developed. Cardiac cells, isolated from neonatal rat heart ventricles, were subjected to elutriation using flow rates that increased step-wise from 20 to 80 ml/min. The cell fraction obtained at 80 ml/min consisted of 68-90% myocytes. Still, upon culturing, the remaining non-myocytes proliferate, causing the proportion of myocytes to decrease to 60 +/- 2% at day 5. A second elutriation protocol was developed in which myocytes and non-myocytes were separated after a period of co-culturing for 4-5 days. By this approach a fibroblast-rich cell fraction (87 +/- 5%) and a myocyte-rich cell fraction (82 +/- 6%) were obtained. In conclusion, centrifugal elutriation creates the opportunity to separate neonatal rat myocytes from non-myocytes, either freshly isolated or after a period of culturing. Particularly, cell separation after a period of culturing ventricular cells offers an advantage to analyse the experimental effects on myocytes and non-myocytes separately.

Intrachanges as part of complex chromosome-type exchange aberrations.

The chromosome-type exchange aberrations induced by ionizing radiation during the G(0)/G(1) phase of the cell cycle are believed to be the result of illegitimate rejoining of chromosome breaks. From numerous studies using chromosome painting, it has emerged that even after a moderate dose of radiation, a substantial fraction of these exchanges is complex. Most of them are derived from the free interaction between the ends of three or more breaks. Other studies have demonstrated that chromosomes occupy distinct territories in the interphase nucleus. Since breaks that are in close proximity have an enhanced interaction probability, it seems likely that after ionizing radiation many of the interacting breaks will be present within one chromosome or chromosome arm. Unfortunately, the majority of these intrachanges remain undetected, even when sophisticated molecular cytogenetic detection methods (i.e. mFISH) are applied to paint all chromosome pairs in distinct colors. In the present paper, we evaluate the limitations of full-color painting for the detection of complex exchanges and the correct interpretations of break interactions.