Kerstin Holmberg

Clonal chromosome aberrations and genomic instability in X-irradiated human T-lymphocyte cultures

To study the effects of X-irradiation on clone forming ability and karyotypic abnormalities in human peripheral blood lymphocytes, cells were exposed to 3 Gy of X-rays in vitro and either individual T-cell clones or long-term T-cell cultures were established. The karyotypes were analyzed in G-banded chromosome preparations after proliferation for 9-34 days in vitro. T-cell clonal karyotype abnormalities were found in 24 of 37 (65%) irradiated and in two of 43 (5%) control clones. Balanced reciprocal translocations and deletions were the predominating types of clonal aberrations. Complex aberrations and unstable karyotypes were found in about half of the irradiated clones. Some of the T-cell clones demonstrated sequential change from normal to aberrant karyotype. Other clones seemed to develop multiple, heterogeneous chromosomal aberrations during growth in vitro. X-Irradiated T-cells grown in long-term T-cell culture displayed karyotype abnormalities in 60-80% of the cells, and the types of aberrations were similar to those found in the individual, irradiated T-cell clones. An increasing number of cells with the same abnormal karyotype was observed when the cultivation time was extended, indicating clonal proliferation. These results demonstrate that a surprisingly high proportion of T-cells with stable and often complex irradiation-induced chromosome aberrations are able to proliferate and form expanding cell clones in vitro. Furthermore, the results indicate that X-irradiation induces latent chromosome damage and genomic instability in human T-lymphocytes.

Delayed Chromosomal Instability in Human T-lymphocyte Clones Exposed to Ionizing Radiation

Recent studies have demonstrated that cells which survive alpha-particle and X-ray exposure may show chromosomal instability, i.e. they continue to develop chromosomal aberrations at an increased frequency for many division cycles after the exposure. To characterize this delayed response, we carried out repeated karyotype analyses of X-irradiated T-lymphocytes during clonal expansion in vitro. Human peripheral blood lymphocytes were obtained from a healthy donor and exposed to 3-Gy X-irradiation. Cell survival, estimated by a cell cloning assay, was 5%. Non-irradiated, control cells were studied in parallel. Monoclonal cell lines were established using the T-cell cloning procedure. G-band karyotype analyses were carried out at several intervals during expansion of the clones for up to 2 months. The irradiated clones did not differ from the control clones with regard to growth rate or cytometric DNA profile. Non-irradiated cell clones showed a normal karyotype, with < 10% of sporadic, non-clonal chromosome and chromatid breaks. In the irradiated clones, the karyotypes showed different (sub)clonal chromosome rearrangements, which developed successively during the cultivation time. In addition to these karyotypic abnormalities, > 20% of the cells in these clones had sporadic, non-clonal chromosome aberrations, and there was a tendency of increasing frequency of such aberrations by length of cultivation. Thus, two types of radiation-induced chromosomal instability were observed; (sub)clonal karyotypic abnormalities and sporadic, non-clonal chromosome aberrations. The frequency and kinetics by which these alterations occur in the progeny of X-irradiated T-cells suggest that they arise through different pathways, and argue against their causation by mutation or persistent DNA damage.

Chromosomal instability in human lymphocytes after low dose rate gamma -irradiation and delayed mitogen stimulation

PURPOSE To study the possibility that radiation induced chromosomal instability in human lymphocytes is promoted by a conflict between mitogen-induced growth stimulation and radiation-induced genotoxic stress. MATERIALS AND METHODS Peripheral blood lymphocytes were exposed to low LET-irradiation at: (1) low-dose rate (LDR, 1-3 Gy, 0.024 Gy h[-1]) in order to minimize genotoxic stress; (2) high dose rate (HDR, 1-3 Gy, 45 Gy h[-1]) followed by immediate mitogen stimulation; and (3) HDR followed by a recovery period of 5 days before mitogen stimulation. Subsequent analyses included cell viability and clonogenic cell survival, chromosome aberrations at the first post-irradiation mitosis, and karyotype analysis of long term cultured cells, 11-57 days after mitogen stimulation. RESULTS Dose (1-3 Gy) and dose rate (LDR and HDR) effects on the frequency of dicentric chromosomes at the first post-irradiation mitosis were in agreement with published data, with a pronounced dose rate effect of 2 and 3 Gy exposures. G-handed karyotypes after 11 days of growth in vitro showed increased frequencies of chromosome breaks and rearrangements in all irradiated cell cultures. Clones with complex karyotype abnormalities and increased frequencies of de novo aberrations developed in the irradiated cultures during extended growth for 22-57 days. These results show that: (1) LDR-irradiation induces chromosomal instability in primary human lymphocytes; (2) mitogen stimulation rescues HDR-irradiated cells from death at the expense of an increased level of chromosome aberrations; and (3) HDR-irradiated cells that are allowed 5 days of recovery before mitogen stimulation develop chromosomal instability during subsequent long-term proliferation. CONCLUSIONS Neither the acute genotoxic stress of HDR-irradiation compared with LDR-irradiation, nor the hypothesized conflict between mitogen-induced growth stimulation and irradiation-induced growth arrest, seem to be critical conditions for the development of chromosomal instability in primary human T lymphocytes. Post-irradiation incubation allowing apoptotic processes to remove damaged cells does not prevent the subsequent development of chromosomal instability during long-term cell proliferation.

Hprt mutations and karyotype abnormalities in T-cell clones from healthy subjects and melphalan-treated ovarian carcinoma patients

In vivo mutations at the locus for hypoxanthine phosphoribosyl transferase (hprt) were studied in 6-thioguanine (TG)-resistant T-lymphocyte clones from healthy male and female subjects and ovarian carcinoma patients treated with melphalan. Southern blot analysis of 108 clones showed alterations in 14% (4/29) of the clones from healthy males, 4.3% (2/47) of the clones from healthy females and 3.1% (1/32) of the clones from melphalan-treated patients. 2 of the 7 abnormal clones had a total deletion of the hprt gene; the others had partial deletions. Karyotype analysis of 82 clones revealed 1 clonal abnormality in 29 mutant clones from healthy males (3.6%). Loss or structural aberration of 1 X-chromosome occurred in 6% of the clones from healthy females. The frequency of karyotypic abnormalities (excluding those affecting one of the X-chromosomes) was significantly higher in clones from patients (37%) as compared to healthy females (5.9%). No aberration was found to affect the hprt locus at Xq27 in any of the 82 clones studied.

Persistence of chromosome rearrangements in peripheral lymphocytes from patients treated with melphalan for ovarian carcinoma

SummaryChromosome aberrations were studied in peripheral lymphocytes from 50 patients treated with melphalan against ovarian carcinoma. The chromosome analyses were carried out 4–132 months (mean 57 months) after the end of melphalan therapy. Most of the patients were studied several times during four years. The mean frequency of cells with chromosome and chromatid aberrations was 5.4% in the patients and 2.3% in an untreated control group. The highest aberration frequency (average 18%) was found in a patient who later developed gastric carcinoma. The dominating types of berrations in the patients were chromosome exchanges occurring as single marker chromosomes or as multiple chromosome rearrangements. These types of aberrations were found in only 0.3% of the control cells as compared to 3.8% of the patient cells. Patients with a high total dose of melphalan (above 420 mg) and a long duration of the therapy (average 22.5 months) had a higher frequency of cells with aberrations (6.3%) than patients with a lower total dose (below 420 mg) and a shorter therapy (12 months) (4.2%). No additive effect of radiation therapy was observed on the aberration frequency.

Radiation induced chromosomal instability in human T-lymphocytes

Chromosomal instability in proliferating mammalian cells is characterized by a persistent increase of chromosomal aberrations and rearrangements occurring de novo during successive cell generations. Recent results from many laboratories using a variety of cells and cytogenetic end points show that this phenotype can be induced by low as well as high LET irradiation. A typical feature of chromosomal instability in primary human G0-lymphocytes exposed to gamma-irradiation at both high dose rate (45 Gy h-1) and low dose rate (0.024 Gy h-1) is the appearance of novel aberrations in the clonal progeny of the irradiated cell, many generations after the exposure. The same phenotype was observed in lymphocytes that were allowed to recover for 5 days in G0 after the radiation exposure, as well as in hprt-mutant T cell clones. These results demonstrate that neither the acute genotoxic stress caused by high dose rate as compared to low dose rate irradiation, nor a hypothesized conflict between mitogen induced growth stimulation and growth arrest due to radiation damage, seem to be critical conditions for the development chromosomal instability in these cells. In contrast to observations in other cells, no evidence of a persistent decrease of cloning ability was observed in the progeny of radiation-exposed human lymphocytes, and no alteration was observed in their sensitivity to a second radiation exposure. Furthermore, the frequency of CA-repeat length variation at three loci was not increased in the progeny of X-irradiated T cells as compared to non-irradiated cells, which indicates that microsatellite instability is not part of the chromosomal instability phenotype in human T-lymphocytes.