Proliferative kinetics and mitomycin C-induced chromosome damage in Fanconi's anemia lymphocytes

Lymphocytes from two sisters with Fanconi's anemia (FA) were studied for cell cycle kinetics, sister chromatid exchanges (SCEs), and chromosomal aberrations when they had undergone one, two, or three or more divisions in mitomycin C (MMC)-treated cultures. Lymphocytes from the parents, another sister of the probands, and a healthy unrelated adult were examined as controls. Analyses of cell cycle kinetics by the sister chromatid differential staining method revealed that the relative frequency of metaphase cells at their third or subsequent divisions was much smaller in untreated FA cultures than in normal cultures fixed at 96 h after phytohemagglutinin stimulation. These data indicate that FA cells proliferate much more slowly than normal cells. MMC treatments of FA and normal cells led to a clearly dose-related delay in cell turnover times, the duration of delay being much longer in FA than in normal cells. FA cells had about 1.4 times higher frequencies of SCEs than normal cells in both MMC-treated and untreated cultures. FA cells also showed several times higher frequencies of chromosomal aberrations than normal cells, and the frequency of chromosomal aberrations decreased through subsequent mitoses by approximately 60% in both FA and normal cells.     

On the localization of mitomycin C-induced aberrations in normal human and Fanconi's anaemia cells

This paper summarizes the results of a series of experiments with primary cultures of normal human fibroblasts and lymphocytes designed to investigate chromatid aberration 'break-point' localization after a 1-h pulse of mitomycin C. For discontinuities and interchanges, 60-70% of the inferred 'break-points' were localized to defined paracentric heterochromatin and the centromeric regions (i.e. approximately 21% by length of the normal karyotype), irrespective of 'dose', aberration frequency, sample time or cycle sub-phase as determined by replication banding. Chromatid intrachanges are non-(or negatively) localized because of an inescapable scoring bias. SCE in fibroblasts show no such localization. Cells from a number of Fanconi's anaemia subjects were examined. In poorly growing cultures, localization was as high as in normal cells but in vigorous cultures localization was reduced to approximately 30%. It is suggested that the enhanced aberration sensitivity of this syndrome could arise because non-localized aberrations, usually eliminated before division in normal cells, are allowed to reach mitosis in FA cells.     

The rate of sister chromatid exchanges parallel to spontaneous chromosome breakage in Fanconi's anemia and to trenimon-induced aberrations in human lymphocytes and fibroblasts.

The incidence of structural chromosome aberrations and the rate of sister chromatid exchanges (SCE) was investigated in lymphocyte cultures from a patient with typical Fanconi's anemia and his parents. The rate of SCEs was found to be normal. In experiments with the alkylating agent Trenimon the SCE rates proved to be a sensitive indicator for the induction of structural aberrations: in presence of an induced aberration rate half as high as the spontaneous rate in the Fanconi's anemia case, the rate of SCEs was found to be quintupled. Dose-effect relationships for the induction of SCE rates by Trenimon were studied over a wide dose range in lymphocyte and fibroblast cultures. The results reflect the same difference in sensitivity earlier observed in the induction of structural chromosome aberrations, fibroblasts being far more sensitive.     

Some observations on the localization of mitomycin C-induced aberrations in human lymphocytes

Actively cycling human lymphocytes were treated with mitomycin C for 1 h (1.4 μg/ml) and then grown in medium containing 10 μg/ml bromodeoxyuridine. Serial 5-h colcemid accumulation samples were taken up to 35 h and the air-dried methaphase spreads stained for replication banding. A complete cell-cycle subphasing analysis was made, and classified cells scored for all categories of chromatid-type aberrations and their location.

Inspite of the high dose which produced massive delay and cycle perturbation, there was no evidence for selectively lethality of early-S cells, in fact such cells were in excess. Extreme localization of aberrations to late-replicating (mostly centromeric) regions was found at all subphases and in pre-S cells. This rules out ‘localization by default’ as an explanation for the observed preferential occurence of ‘break points’ in these regions.

The frequency of incomplete intrachanges, low in late S, rises dramaticallyin early S to become maximal in pre-S cells.     

Frequency and distribution of mitomycin C-induced structural chromosome aberrations in lymphocytes from non-Hodgkin lymphoma patients

Lymphocytes from 15 untreated patients with non-Hodgkin lymphoma (NHL) and 15 controls were exposed to 0.08 micrograms/ml mitomycin C, and the frequency and distribution of structural chromosome aberrations (chromatid and chromosome gaps, breaks, and exchanges) were analyzed in 100 mitoses per subject. The mean frequencies of aberrant cells, and gap, break, and gap + break events were 8.7, 0.9, 9.7, and 10.6 in the NHL group and 11.6, 1.1, 12.7, and 13.8 in the control group. None of the differences between the two groups was significant (P greater than 0.05). The distribution of breakpoints was nonrandom (P less than 0.001) in both groups, with a particularly marked excess of breaks in 9q11. The other breakage-prone bands were 1q11 and 1q21 in the NHL group and 1p11, 1q11, 2q31, and 16q11 in the control group. None of these hot spots coincided with any of the 60 bands known to be involved in primary chromosome abnormalities in NHL.     

Relationship of spontaneous chromosome instability and sister chromatid exchanges in Fanconi's anemia

The frequency of spontaneous instability of lymphocyte chromosomes of the first 2 mitoses, the rate of sister chromatid exchanges (SCEs), and the proliferative kinetics of lymphocytes were studied in a 6-year-old girl with Fanconi's anemia (FA) and in 4 healthy donors. The frequencies of aberrant cells and the total number of chromosome breaks in the FA patient decreased with cell transition from the first to the second mitosis. The FA lymphocytes had a slower proliferative kinetics and the level of SCEs was higher as compared with control. The probability of chromatid deletions at the sites of SCEs localization and in the dark and light stained chromatids was unequal. 33.8% of chromatid breaks were associated with SCEs. The data point to the relationship between SCEs and spontaneous chromosome instability in AF cells.     

Repair analysis of mitomycin C-induced DNA crosslinking in ribosomal RNA genes in lymphoblastoid cells from Fanconi's anemia patients

The repair of mitomycin C (MMC)-induced DNA crosslinking was analyzed by denaturation-renaturation gel electrophoresis in ribosomal RNA genes in lymphoblastoid cell lines from 4 patients with Fanconi's anemia (FA). In comparison to normal lymphoblastoid cell lines, 2 lines of FA cells belonging to complementation group A clearly exhibited higher sensitivity to MMC and an almost identical deficiency in the removal of DNA crosslinking. A complementation group B cell line, HSC 62, exhibited a lower sensitivity than group A cells and a lesser deficiency in crosslink repair. Another 'non-A' group cell line, HSC 230, reproducibly exhibited even higher sensitivity to MMC than group A cells. The results on MMC crosslinkage removal at the molecular level correlated well with cell survival. The observed subtle differences of repair among the 4 FA cell lines might represent possible genetic differences in the respective FA complementation groups.     

The influence of caffeine on the mitomycin C-induced chromosome aberration frequency in normal human and xeroderma pigmentosum cells

The clastogenic effect of mitomycin C (MC) was determined in two normal fibroblast cell lines and two xeroderma pigmentosum (XP) cell lines, a variant and a group A excision-deficient line. The group A xeroderma cell line was substantially more sensitive to MC than either the XP variant or the normal human cells. On caffeine post-treatment potentiation of the MC-induced aberration frequency occurred in all the cell lines. The XP varian cell line exhibited a distinctly higher sensitivity to caffeine than the classical XP or the normal human cell lines.     

Defective repair of mitomycin C crosslinks in Fanconi's anemia and loss in confluent normal human and xeroderma pigmentosum cells

Crosslink repair of mitomycin C-induced interstrand crosslinks was studied in exponentially growing and confluent normal human, transformed WI38CT-1, Fanconi's anemia (FA) and xeroderma pigmentosum (XP) group-A fibroblasts by the assay methods of alkaline sucrose centrifugation, hydroxyapatite column chromatography and S₁-nuclease digestion. These three methods demonstrated unequivocally that crosslinking occurred at a rate of 0.13 crosslinks/10⁸ Da per μg per ml mitomycin C ( 10 μg/ml) and the first half-excision of crosslinks followed the rapid first-order kinetics of 2–3 h half-life in exponentially-growing normal, WI38CT-1 and XP group-A cells. However, the first half-excision was completely defective in three out of the four FA strains tested and severely retarded in an FA strain. These results strongly support our previous observations in different strains of normal human, FA and XP group-A cells. An important new addition is that confluent, otherwise proficient, normal and XP cells almost completely lost the ability of the first, rapid half-excision of mitomycin C crosslinks in their DNA. This probably suggests that the enzyme or regulatory factor responsible for the half-excision, which differs from that for nucleotide excision repair, present constitutively in confluent cells, may be induced or activated only in the cycling cells. However, its relation to a defective FA factor is not clear at present.     

Defective repair of mitomycin C crosslinks in Fanconi's anemia and loss in confluent normal human and xeroderma pigmentosum cells

Crosslink repair of mitomycin C-induced interstrand crosslinks was studied in exponentially growing and confluent normal human, transformed W138CT-1, Fanconi's anemia (FA) and xeroderma pigmentosum (XP) group-A fibroblasts by the assay methods of alkaline sucrose centrifugation, hydroxyapatite column chromatography and S1-nuclease digestion. These three methods demonstrated unequivocally that crosslinking occurred at a rate of 0.13 crosslinks/10(8) Da per microgram per ml mitomycin C (less than or equal to 10 micrograms/ml) and the first half-excision of crosslinks followed the rapid first-order kinetics of 2-3 h half-life in exponentially-growing normal, WI38CT-1 and XP group-A cells. However, the first half-excision was completely defective in three out of the four FA strains tested and severely retarded in an FA strain. These results strongly support our previous observations in different strains of normal human, FA and XP group-A cells. An important new addition is that confluent, otherwise proficient, normal and XP cells almost completely lost the ability of the first, rapid half-excision of mitomycin C crosslinks in their DNA. This probably suggests that the enzyme or regulatory factor responsible for the half-excision, which differs from that for nucleotide excision repair, present constitutively in confluent cells, may be induced or activated only in the cycling cells. However, its relation to a defective FA factor is not clear at present.     

Antagonistic effect of cocultivation on mitomycin C-induced aberration rate in cells of a patient with Fanconi's anemia and in Chinese hamster ovary cells

Summary The rate of spontaneous chromosomal aberrations in fibroblasts of a patient with Fanconi's anemia was slightly reduced after cocultivation with Chinese hamster ovary (CHO) cells. However, after mitomycin C treatment, a significant reduction of induced chromosomal damage was found in the FA cells while a significant increase was observed in the CHO cells. This antagonistic effect could be attributed to some diffusible agent(s). The results are discussed with respect to the underlying mechanism of the disease.     

Suppression of mitomycin C-induced micronuclei in mouse bone marrow cells by post-treatment with vanillin

Induction of micronuclei by mitomycin C (MMC) in mouse bone marrow cells was suppressed by post-treatment with vanillin, a component of vanilla essence flavour. Vanillin was given orally to mice 7.5 h after intraperitoneal injection of 2 mg/kg MMC. Post-treatment with vanillin at 500 mg/kg caused about 50% decrease in the frequency of micronucleated polychromatic erythrocytes (MN-PCEs). The effect of vanillin administration on the time-course of formation of MN-PCEs was also investigated. The suppressing effect was not due to a delay in the formation of MN-PCEs by the cytotoxic action of vanillin. Vanillin acts as an anticlastogenic factor in vivo.     

UV-Repair is impaired in fibroblasts from patients with Fanconi's anemia

Summary Fanconi's anemia, a hereditary autosomal disease with chromosomal instability, elevated incidence of cancer and clinical symptoms is accompanied by a DNA repair deficiency. Fibroblasts from patients with Fanconi's anemia were found to be impaired in the DNA repair of UV damage. Nucleoid decondensation and recondensation after UV irradiation were less efficient in fibroblasts from patients with Fanconi's anemia than in those from a healthy proband. These data confirm our earlier findings that DNA ligase is deficient in Fanconi's anemia.     

Prevention of chromosomal breakage in Fanconi's anemia by cocultivation with normal cells

Summary The frequency of aberration in cultured lymphocytes from patients with Fanconi's anemia was significantly reduced when the cells were cocultivated with normal human lymphocytes. The results suggest that most of the chromosomal aberrations observed in cultured cells from Fanconi patients arise during cultivation and that the presence of normal cells prevents chromosomal damage by means of a hitherto unknown mechanism.     

The distribution of spontaneous chromosome aberrations in BHK21/C13 fibroblasts.

Previous investigations of spontaneous aberrations in mammalian cells have been carried out on large heterogeneous samples of individuals, each of whom had had a different exposure to exogenous clastogens. In the present analysis using Syrian Hamster cells, a large number of metaphases were analysed from one sample of control cells. In this way all cells were exposed to the same doses of any unknown clastogens. The overall distribution of spontaneous breaks was found to be nonrandom. Breaks involved in different types of aberration had a nonrandom distribution, which was specific for each type. (e.g. terminal deletion and rearrangement).     

Premature chromosome condensation in a case of Fanconi's anemia.

Evidence is presented for the occurrence of premature chromosome condensation (PCC) from micronuclei even in the first in vitro mitoses in a case of Fanconi's anemia.