Telomere shortening: a new prognostic factor for cardiovascular disease post-radiation exposure.

Telomere length has been proposed as a marker of mitotic cell age and as a general index of human organism aging. Telomere shortening in peripheral blood lymphocytes has been linked to cardiovascular-related morbidity and mortality. The authors investigated the potential correlation of conventional risk factors, radiation dose and telomere shortening with the development of coronary artery disease (CAD) following radiation therapy in a large cohort of Hodgkin lymphoma (HL) patients. Multivariate analysis demonstrated that hypertension and telomere length were the only independent risk factors. This is the first study in a large cohort of patients that demonstrates significant telomere shortening in patients treated by radiation therapy who developed cardiovascular disease. Telomere length appears to be an independent prognostic factor that could help determine patients at high risk of developing CAD after exposure in order to implement early detection and prevention.

Increased genomic alteration complexity and telomere shortening in B-CLL cells resistant to radiation-induced apoptosis.

B-cell chronic lymphocytic leukemia (B-CLL) results in an accumulation of mature CD5(+)/CD23(+) B cells due to an uncharacterized defect in apoptotic cell death. B-CLL is not characterized by a unique recurrent genomic alteration but rather by genomic instability giving rise frequently to several chromosomal aberrations. Besides we reported that approximately 15% of B-CLL patients present malignant B-cells resistant to irradiation-induced apoptosis, contrary to approximately 85% of patients and normal human lymphocytes. Telomere length shortening is observed in radioresistant B-CLL cells. Using fluorescence in situ hybridization (FISH) and multicolour FISH, we tested whether specific chromosomal aberrations might be associated with the radioresistance of a subset of B-CLL cells and whether they are correlated with telomere shortening. In a cohort of 30 B-CLL patients, all of the radioresistant B-CLL cell samples exhibited homozygous or heterozygous deletion of 13q14.3 in contrast to 52% of the radiosensitive samples. In addition to the 13q14.3 deletion, ten out of the 11 radioresistant B-cell samples had another clonal genomic alteration such as trisomy 12, deletion 17p13.1, mutation of the p53 gene or translocations in contrast to only three out of 19 radiosensitive samples. Telomere fusions and non-reciprocal translocations, hallmarks of telomere dysfunction, are not increased in radioresistant B-CLL cells. These findings suggest (i) that the 13q14.3 deletion accompanied by another chromosomal aberration is associated with radioresistance of B-CLL cells and (ii) that telomere shortening is not causative of increased clonal chromosomal aberrations in radioresistant B-CLL cells.

TRF2 inhibition promotes anchorage-independent growth of telomerase-positive human fibroblasts.

Although telomere instability is observed in human tumors and is associated with the development of cancers in mice, it has yet to be established that it can contribute to the malignant transformation of human cells. We show here that in checkpoint-compromised telomerase-positive human fibroblasts an episode of TRF2 inhibition promotes heritable changes that increase the ability to grow in soft agar, but not tumor growth in nude mice. This transforming activity is associated to a burst of telomere instability but is independent of an altered control of telomere length. Moreover, it cannot be recapitulated by an increase in chromosome breaks induced by an exposure to gamma-radiations. Since it can be revealed in the context of telomerase-proficient human cells, telomere dysfunction might contribute to cancer progression even at late stages of the oncogenesis process, after the telomerase reactivation step.

Chromosome aberrations and cell inactivation induced in mammalian cells by ultrasoft X-rays: correlation with the core ionizations in DNA.

PURPOSE: To study the frequency of chromosome aberrations induced by soft X-rays. To see if the core ionization of DNA atoms is involved in this end-point as much as it appears to be in cell killing. MATERIALS AND METHODS: V79 hamster cells were irradiated by synchrotron radiation photons iso-attenuated in the cell (250, 350, 810eV). The morphological chromosome aberrations detected in the first post-irradiation cell division (dicentrics and centric rings) were studied by Giemsa staining. RESULTS: The chromosome aberrations at 350eV were, respectively, 2.6 +/- 0.8 and 2.1 +/- 0.8 times more numerous than at 250 and 810eV for the same average dose absorbed by the nucleus. These relative effectivenesses are comparable with the ones already measured for cell killing. Moreover, they roughly vary such as the relative numbers of core ionizations (including in the phosphorus L-shell) produced in DNA and its bound water (water being involved only at 810eV through the oxygen atoms). In particular, they reproduce the characteristic twofold enhancement at 350eV, above the carbon K threshold. CONCLUSIONS: Correlations suggest that the core ionization process is likely a common and essential mechanism initiating both chromosome aberration and cell killing end-points at these photon energies.

Biological effects induced by K photo-ionisation in and near constituent atoms of DNA.

In order to assess the lethal efficiency and other biological effects of inner shell ionisations of constituent atoms of DNA ('K' events), experiments were developed at the LURE synchrotron facility using ultrasoft X rays as a probe of K events. The lethal efficiency of ultrasoft X rays above the carbon K threshold was especially investigated using V79 cells and compared with their efficiency to induce double strand breaks in dry plasmid-DNA. A correlation between the K event efficiencies for these processes is shown. Beams at 340 eV were found to be twice as efficient at killing cells than were beams at 250 eV. In addition, a rough two-fold increase of the relative biological effectiveness for dicentric + ring induction has also been observed between 250 and 340 eV radiations.

Cell inactivation and double-strand breaks: the role of core ionizations, as probed by ultrasoft X rays.

The large RBE (approximately 7) measured for the killing of Chinese hamster V79 cells by 340 eV ultrasoft X rays, which preferentially ionize the K shell of carbon atoms (Hervé du Penhoat et al., Radiat. Res. 151, 649-658, 1999), was used to investigate the location of sensitive sites for cell inactivation and the physical modes of action of radiation. The enhancement of the RBE above the carbon K-shell edge either may indicate a high intrinsic efficiency of carbon K-shell ionizations (due, for example, to a specific physical or chemical effect) or may be related to the preferential localization of these ionizations on the DNA. The second interpretation would indicate a strong local (within 3 nm) action of K-shell ionizations and consequently the importance of a direct mechanism for radiation lethality (without excluding an action in conjunction with an indirect component). To distinguish between these two hypotheses, the efficiencies of core ionizations in DNA atoms (phosphorus L-shell, carbon K-shell, and oxygen K-shell ionizations) to induce damages were investigated by measuring their capacities to produce DNA double-strand breaks (DSBs). The effect of photoionizations in isolated DNA was studied using pBS plasmids in a partially hydrated state. No enhancement of the efficiency of DSB induction by carbon K-shell ionizations compared to oxygen K-shell ionizations was found, supporting the hypothesis that it is the localization of these carbon K-shell events on DNA which gives to the 340 eV photons their high killing efficiency. In agreement with this interpretation, cell inactivation and DSB induction, which do not appear to be correlated when expressed in terms of yields per unit dose in the sample, exhibit a rather good correlation when expressed in terms of efficiencies per core event in the DNA. These results suggest that core ionizations in DNA, through core-hole relaxation in conjunction with localized effects of spatially correlated secondary and Auger electrons, may be the major critical events for cell inactivation, and that the resulting DSBs (or a constant fraction of these DSBs) may be a major class of unrepairable lesions.

Lethal effect of carbon K-shell photoionizations in Chinese hamster V79 cell nuclei: experimental method and theoretical analysis.

To test a possible specific effect of carbon K-shell ionizations in DNA, survival curves for Chinese hamster V79 cells were measured for X irradiations at energies below and above the carbon K-shell ionization threshold. Specific values of the X-ray energies (250 and 340 eV) were chosen to ensure isoattenuation of the two kinds of radiation within the cell. An enhancement of lethality by a factor of about 2 was found for X rays at 340 eV compared to below the threshold at 250 eV. This may be attributed to the production of highly efficient carbon K-shell ionizations located on DNA. A model of X-ray lethality (Goodhead et al., Radiat. Prot. Dosim. 52, 217-223, 1994) was extended to allow for a possible lethal effect from clusters of reactive species induced by K-shell photoionizations (K-shell clusters). Within this model, the increase in lethality above the carbon K-shell threshold may be explained by a value of 2% for the lethal efficiency of K-shell clusters overlapping the DNA. An extrapolation to the lethal effect of more complex ion-induced K-shell ionizations indicates that K-shell ionization may be a major process in the biological effectiveness of heavy ions.

Alterations of DNA methylation patterns in germ cells and Sertoli cells from developing mouse testis.

In situ alterations of DNA methylation were studied between 14 d postcoitum and 4 d postpartum in Sertoli cells and germ cells from mouse testis, using anti-5-methylcytosine antibodies. Compared to cultured fibroblasts, Sertoli cells display strongly methylated juxtacentromeric heterochromatin, but hypomethylated chromatids. Germ cells always possess hypomethylated heterochromatin, whereas their euchromatin passes from a demethylated to a strongly methylated status between days 16 and 17 postcoitum. This hypermethylation occurs in the absence of DNA replication, germ cells being blocked in the G(0)-G(1) phase from day 15 postcoitum to birth. The DNA hypermethylation of germ cells is maintained until birth and could be visualized on both chromatids of metaphase chromosomes at the first postpartum cell division. Subsequently, the DNA hypermethylation is lost semiconservatively, being replaced by a methylation pattern recalling the typical fibroblast pattern. These alterations of DNA methylation follow a strict chronology, are chromosome structure and cell-type dependent, and may underlie profound changes of genome function.

Increased radiation-induced chromosome breakage after progesterone addition at the G1/S-phase transition.

Pregnant females appear to have an increased chromosomal sensitivity to gamma-irradiation. This hypersensitivity was found to parallel the increase of gestation hormone amounts [M. Ricoul, L. Sabatier, B. Dutrillaux, Increased chromosome radiosensitivity during pregnancy, Mutat. Res. 374(1997) 73-78]. An in vitro experiment was developed to study the effect of progesterone. We performed irradiations of whole blood from normal human donors and chromosome were analysed in first generation metaphases. By comparison to untreated controls, all cultures in which progesterone was added around the 24th h of culture exhibited an increased frequency of chromosome rearrangements, principally dicentrics and rings, which confirms the role of progesterone in the results of in vivo studies. BrdU incorporation studies suggested that progesterone was particularly efficient just before the entry into S-phase, which corresponds to the G1/S transition period. Cultures with an increased frequency of chromosome breakage had a slightly higher mitotic index than controls. It is suggested that progesterone may stimulate DNA repair in cells which reached the end of G1-phase with unrepaired breaks. This would allow the cells to enter the S-phase and survive, although some illegitimate repair leads to chromosome rearrangements, visible at the following metaphase.

Requirement of poly(ADP-ribose) polymerase in recovery from DNA damage in mice and in cells.

Poly(ADP-ribose) polymerase [PARP; NAD+ ADP-ribosyltransferase; NAD+: poly(adenosine-diphosphate-D-ribosyl)-acceptor ADP-D-ribosyltransferase, EC 2.4.2.30] is a zinc-finger DNA-binding protein that detects specifically DNA strand breaks generated by genotoxic agents. To determine its biological function, we have inactivated both alleles by gene targeting in mice. Treatment of PARP-/- mice either by the alkylating agent N-methyl-N-nitrosourea (MNU) or by gamma-irradiation revealed an extreme sensitivity and a high genomic instability to both agents. Following whole body gamma-irradiation (8 Gy) mutant mice died rapidly from acute radiation toxicity to the small intestine. Mice-derived PARP-/- cells displayed a high sensitivity to MNU exposure: a G2/M arrest in mouse embryonic fibroblasts and a rapid apoptotic response and a p53 accumulation were observed in splenocytes. Altogether these results demonstrate that PARP is a survival factor playing an essential and positive role during DNA damage recovery.

Dosimetric and cytogenetic studies of multiple radiation-induced meningiomas for a single patient.

No criteria are currently available to determine the spontaneous or radiation-induced origin of a malignant tumor occurring in a previously irradiated area. This study presents the dosimetric and cytogenetic analysis of meningiomas diagnosed in irradiated brain areas from a single patient and a discussion of the karyotypes of spontaneous meningiomas and radiation-induced tumors published in the literature.

Increased chromosome radiosensitivity during pregnancy.

It was necessary to consider the risks of exposure of pregnant women, not only in relation to the child, but also in relation to their own hypersensitivity. We have demonstrated that pregnancy increases radiosensitivity of chromosome in the mouse at the end of gestation. This is of importance since it may have implications on radioprotection of pregnant women and give experimental guidelines to the problems of hypersensitivity to drugs and cancer aggravation during pregnancy. Blood obtained from women at various times of pregnancy was exposed to ionizing radiations. By comparison to non-pregnant women, an increase in chromosome breakage was observed in metaphases from lymphocytes, after short-term culture in the presence of the serum of the same donor. Immediately after delivery, this increase in radiosensitivity disappeared. In a prospective study, serial analyses showed a very strong correlation between the amount of pregnancy hormones, progesterone in particular, and the increase in radiosensitivity. Pregnant women may have an increased sensitivity to ionizing radiation during the second half of their pregnancy. This study provides the first evidence in human that radiosensitivity may vary in relation to physiological conditions.

Radiation-induced chromosome damage in astronauts' lymphocytes.

The increased number of manned space missions has made it important to estimate the biological risks encountered by astronauts. As they are exposed to cosmic rays, especially ions with high linear energy transfer (LET), it is necessary to estimate the doses they receive. The most sensitive biological dosimetry used is based on the quantification of radiation-induced chromosome damage to human lymphocytes. After the space missions ANTARES (1992) and ALTAIR (1993), we performed cytogenetic analysis of blood samples from seven astronauts who had spent from 2 weeks to 6 months in space. After 2 or 3 weeks, the X-ray equivalent dose was found to be below the cytogenetic detection level of 20 mGy. After 6 months, the biological dose greatly varied among the astronauts, from 95 to 455 mGy equivalent dose. These doses are in the same range as those estimated by physical dosimetry (90 mGy absorbed dose and 180 mSv equivalent dose). Some blood cells exhibited the same cytogenetic pattern as the 'rogue cells' occasionally observed in controls, but with a higher frequency. We suggest that rogue cells might result from irradiation with high-LET particles of cosmic origin. However, the responsibility of such cells for the long-term effects of cosmic irradiation remains unknown and must be investigated.

A cytogenetic study of 19 recurrent gliomas.

A cytogenetic analysis was performed on 19 recurrent gliomas all of which had been treated by radiotherapy. All cases exhibited clonal chromosomal anomalies, the tumors were classified into four categories in relation to their mono- or polyclonality and to the presence or absence of a clonal evolution. Polyclonal tumors without clonal evolution had a delay of recurrence significantly longer than monoclonal or polyclonal tumors with clonal evolution. This difference could be related to the presence of clones with different malignant potential, which could be differentiated by their pattern of chromosomal aberrations. The malignant potential of "highly malignant" clones resulted from the juxtaposition of imbalances, such as monosomy 10, as in high-grade primary gliomas, and presumably radiation-induced structural rearrangements. That of clones of low malignancy was almost limited to the presence of multiple balanced structural rearrangements, probably induced by radiation.

Clonal rearrangements in human irradiated fibroblasts.

The cytogenetic dose response following in vivo localized irradiation is difficult to establish because of the occurrence of clones defined by chromosome alterations, with various proliferative rates. The biological meaning of these clones is not well understood. Two sets of experiments were performed to follow their behavior. R-banded karyotypes were established on human fibroblasts irradiated either before or after initiation of the cultures. Clones were observed in cultures developed after irradiation of biopsies, whereas irradiated cultures exhibited karyotypes with multiple non-clonal rearrangements. This difference suggests that most radiation-induced chromosome anomalies do not confer a selective advantage on the carrier cells in vitro. The appearance of clonal anomalies following biopsy irradiation would rather be a consequence of a strong selection at the time of the growth of the cells out of the explants, which would give rise to the progeny of a limited number of progenitor cells.

Decrease in catalase activity and loss of the 11p chromosome arm in the course of SV40 transformation of human fibroblasts.

The activity of catalase, a key enzyme in cell detoxication of oxygen derivatives, was studied in SV40 transformed human fibroblasts. A cytogenetic study was performed in parallel to establish a quantification of 11p arm on which the corresponding gene is mapped. mRNA amounts were determined by Northern blotting. At early passages, catalase activity strongly decreased whereas the corresponding mRNA was present. No deletions of 11p arms were detected. At later passages, catalase activity remained low. 11p arm deletions were frequent, and the amount of mRNA was decreased. In these late passages, the good correlation between the number of 11p arms and catalase activity suggested a gene dosage effect. It is assumed that the decrease of catalase activity provides a selective advantage for the transformed cells. This decrease is related to a post-transcriptional change of regulation at early passages and to the loss of the corresponding gene at later passages.

Chromosome anomalies in mammary carcinoma from transgenic WAPRAS mice: compression with human data.

Transgenic WAPRAS mice, obtained by infection of the construct WAP promoter murine gene and the HRAS human protooncogene, develop mammary adenocarcinoma within 1-3 months after pregnancy. A cytogenetic analysis was performed on 17 tumors from 10 mice. Almost all detected anomalies were chromosome gains. The resulting trisomies affected recurrently chromosomes 1, 15, 19, 17, 7, and 12, in decreasing order of involvement. Although in situ hybridization showed that the transgene was integrated in chromosome 1, the duplication of this chromosome did not depend on the presence or absence of the transgene. Comparison with human data indicates that the 3 most frequently duplicated chromosomes in WAPRAS mice correspond to the human chromosome segments most frequently duplicated or amplified in breast cancer, i.e., 1q, 8q, and 11q13. None of the chromosome segments often deleted in human tumors were found to be duplicated in the mouse tumors.

Specific chromosome instability induced by heavy ions: a step towards transformation of human fibroblasts?

Cultures of human skin fibroblasts were exposed to heavy ions: neon (E = 10.74 MeV/u) and argon (E = 10.52 MeV/u) at fluences of 10(6), 2 x 10(6) and 4 x 10(6) and lead (E = 9.5 MeV/u) at a fluence of 2 x 10(6) particles/cm2. Cultures were further prolonged for up to 25 passages and karyotyping was performed at various times. Radiation-induced chromosome anomalies progressively decreased, became quite rare at passages 5-7 and increased at later passages. Around passages 20-25, most anomalies occurring were dicentrics, involving telomeric regions of 13p and q arms principally and to a lesser degree those of 1p, 16p and 16q arms. These non-random rearrangements paralleled the appearance of clones with unbalanced karyotypes. In particular, two independent proliferating clones were characterized by a monosomy 13. It is concluded that most chromosome lesions directly induced by heavy ions are hardly compatible with cell survival and thus disappear after a few cell generations. However, surviving cells acquire a de novo chromosome instability leading to the formation of clones with unbalanced karyotypes at late passages.

Alterations of the glutathione cycle enzymes during and after SV40-transformation of human fibroblasts.

The activities of several enzymes involved in the antioxidant system of the cell were studied in parallel to cytogenetic alterations at various times after SV40 infection and transformation of human fibroblasts. At early passages after SV40 infection, glutathione reductase (GSR), glutathione peroxidase (GPX), glutathione transferase (GST) and glucose-6-phosphate dehydrogenase (G6PD) activities were decreased. This, associated with the low superoxide dismutase (SOD) and catalase activities previously noticed in these cells, suggested that they are in a highly pro-oxidant status. Although chromosomes carrying the genes encoding these enzymes are frequently underrepresented, there is no direct relationship between the number of chromosomes and enzyme activities. Except for GPX, all the activities tend to increase in established cell lines reaching levels comparable to those of non-transformed fibroblasts. The late increase of G6PD activity may correlate with the frequent duplication of the early replicating X. GSR seems to correlate with G6PD activity and GPX to SOD total activity. The most striking alterations affect mitochondrial and peroxisomal enzymes activities: SOD, GPX and catalase.

Early superoxide dismutase alterations during SV40-transformation of human fibroblasts.

The expression of superoxide dismutases (SOD) 1 and 2 was studied in 4 clones of human fibroblasts after their infection by simian virus 40 (SV40), in parallel with the alterations of chromosomes 21 and chromosome 6q arms, carrying the genes that encode for SOD1 and SOD2 respectively. For all clones, a similar scheme with 2 main phases was observed for both chromosome and SOD variations. The first phase, defined as the pre-crisis phase, was characterized by chromosomal instability, but maintenance of normal numbers of chromosome 6q arms and chromosomes 21. The level of SOD2 mRNA was high, while SOD2 activity and immunoreactive protein were low. SOD1 protein and activity were decreased. In the second phase, defined as the post-crisis phase, the accumulation of clonal chromosomal rearrangements led to the loss of 6q arms, while the number of chromosomes 21 remained normal. SOD2 mRNA level was decreased and SOD2 immunoreactive protein and activity remained low. SOD1 protein and activity increased with passages, reaching values similar to those of control cells at late passages. As in established SV40-transformed human fibroblast cell lines, good correlation was found between SOD2 activity and the relative number of 6q arms. These results allow us to reconstruct the sequence of events leading to the decrease of SOD2, a possible tumor-suppressor gene, during the process of SV40-transformation of human fibroblasts.