The influence of DNA double-strand break structure on end-joining in human cells.

DNA end-joining is the major repair pathway for double-strand breaks (DSBs) in higher eukaryotes. To understand how DSB structure affects the end-joining process in human cells, we have examined the in vivo repair of linearized plasmids containing complementary as well as several different configurations of non-complementary DNA ends. Our results demonstrate that, while complementary and blunt termini display comparable levels of error-free rejoining, end-joining fidelity is decreased to varying extents among mismatched non-complementary ends. End structure also influences the kinetics of repair, accurately recircularized substrates for blunt and complementary termini being detected significantly earlier than for mismatched non-complementary ends. These results suggest that the end-joining process is composed of an early component, capable of efficiently repairing substrates requiring a single ligation event, and a late component, involved in the rejoining of complex substrates requiring multiple processing steps. Finally, these two types of repair events may have different genetic requirements as suggested by the finding that exposure of cells to wortmannin, a potent inhibitor of phosphatidylinositol 3-related kinases (PI 3-related kinases), blocks the repair of complex substrates while having little or no effect on those requiring a simple ligation event.

Arrest of S-phase progression is impaired in Fanconi anemia cells.

Fanconi anemia (FA) is an inherited cancer-susceptibility disorder, characterized by genomic instability, hypersensitivity to DNA cross-linking agents, and a prolonged G2 phase of the cell cycle. We observed a marked dose-dependent accumulation of FA cells in the G2 compartment after treatment with 4,5',8-trimethylpsoralen (Me(3)Pso) in combination with 365 nm irradiation. Using bivariate DNA distribution methodology, we determined the proportion of replicating and arresting S-phase cells and observed that, whereas normal cells arrested DNA replication in the presence of Me(3)Pso cross-links and monoadducts, FA lymphoblasts failed to arrest DNA synthesis. Taken together, the above data suggest that, in response to damage induced by DNA cross-linking agents, the S-phase checkpoint is inefficient in FA cells. This would lead to accumulation of secondary lesions, such as single- and double-strand breaks and gaps. The prolonged time in G2 phase seen in FA cells therefore exists in order to allow the cells to remove lesions which accumulated during the preceding abnormal S phase.

Molecular spectra of HPRT deletion mutations in circulating T-lymphocytes in Fanconi anemia patients.

The principal cellular feature of Fanconi anemia (FA), an inherited cancer prone disorder, is a high level of chromosomal breakage, amplified after treatment with crosslinking agents. Three of the eight genes involved in FA have been cloned: FANCA, FANCC and FANCG. However, their biological functions remain unknown. We previously observed an excessive production of deletions at the HPRT locus in FA lymphoblasts belonging to the relatively rare complementation group D(1) and an increased frequency of glycophorin A (GPA) variants in erythrocytes derived from FA patients (2). In thi study, we examined the molecular nature of 31 HPRT mutations formed in vivo in circulating T-lymphocytes isolated from 9 FA male patients. The results show that in all FA patients investigated the deletions are by far the most prevalent mutational event in contrast to age matched healthy donors, in which point mutations predominate. The complementation group in the FA patients examined in the present study has not yet been defined. However, knowing that mutations in the FANCA and FANCC gene are found to be involved in at least 70% of the FA patients, it can be expected that the excessive production of deletions is a general feature of the FA phenotype. In addition, the spectrum of HPRT deletions observed in FA patients differs from that of healthy children: there is a high frequency of 3'-terminal deletions and a strikingly low proportion of V(D)J mediated events. Based on previous findings, a decreased fidelity of coding V(D)J joint formation (3) and an inaccurate repair of specific DNA double strand breaks via Non-Homologous End Joining (4), we propose that FA genes play a role in the control of the fidelity of rejoining of specific DNA ends. Such a defect may explain several basic features of FA, such as chromosomal instability and deletion pronenness.

Biological consequences of the heterogeneous irradiation of lymphocytes during technetium-99m hexamethylpropylene amine oxime white blood cell labelling.

Technetium-99m hexamethylpropylene amine oxime (99mTc-HMPAO) labelling of white blood cells, routinely used for the detection of infection, results in the incorporation of radioactivity by polymorphonuclear leucocytes and also lymphocytes and can induce cell lesions in the latter case. The aim of this study was therefore to acquire data on the morphological and functional status of labelled lymphocytes present in the 99mTc-HMPAO leucocyte mixture and to determine the cellular consequences of labelling. The mean radioactivity associated with lymphocytes was 325 +/- 10.8 kBq/10(6) lymphocytes under standard labelling conditions. Microautoradiographic studies showed that labelling was heterogeneous (4% intensely labelled cells), which prevented calculation of the mean absorbed dose. The frequency of chromosomal aberrations (dicentrics and rings) in the labelled lymphocytes for 380 kBq/10(6) cells was 1.08 +/- 0.09 but no abnormality was observed in the unlabelled control lymphocytes. The plating efficiency of labelled lymphocytes was reduced, as compared with that for control cells, but some lymphocytes were still able to form clones and were still "alive" by radiobiological definition. It is therefore suggested that lymphocytes should be removed from 99mTc-HMPAO cell preparations before administration to patients.

An analysis of in vivo hprt mutant frequency in circulating T-lymphocytes in the normal human population: a comparison of four datasets.

In this paper, we have compared mutant frequency data at the hprt locus in circulating T-lymphocytes from four large datasets obtained in the UK (Sussex), the USA (Vermont), France (Paris) and The Netherlands (Leiden). In total, data from > 500 non-exposed individuals ranging in age from newborns (cord blood samples) to > 80 years old have been included in the analysis. Based on raw data provided by the four laboratories, a model is presented for the analysis of mutant frequency estimations for population monitoring. For three of the laboratories, a considerable body of data was provided on replicate estimates of mutant frequency from single blood samples, as well as estimates from repeat blood samples obtained over a period of time from many of the individual subjects. This enabled us to analyse the sources of variation in the estimation of mutant frequency. Although some variation was apparent in the results from the four laboratories, overall the data were in general agreement. Thus, in all laboratories, cellular cloning efficiency of T-cells was generally high (> 30%), although in each laboratory considerable variation between experiments and subjects was seen. Mutant frequency per clonable T-cell was in general found to be inversely related to cloning efficiency. With the exception of a few outliers (which are to be expected), mutant frequencies at this locus were in the same range in each dataset; no effect of subject gender was found, but an overall clear age effect was apparent. When log mutant frequency was analysed vs log (age + 0.5) a consistent trend from birth to old age was seen. In contrast, the effect of the smoking habit did differ between the laboratories, there being an association of smoking with a significant increase in mutant frequency in the Sussex and Leiden datasets, but not in those from the Vermont or Paris datasets. Possible reasons for this are discussed. One of the objectives of population monitoring is an ability to detect the effect of accidental or environmental exposure to mutagens and carcinogens among exposed persons. The large body of data from non-exposed subjects we have analysed in this paper has enabled us to estimate the size of an effect that could be detected, and the number of individuals required to detect a significant effect, taking known sources of variation into account.(ABSTRACT TRUNCATED AT 400 WORDS)

Frequencies of HPRT- lymphocytes and glycophorin A variants erythrocytes in Fanconi anemia patients, their parents and control donors.

The mutant frequency of 6-thioguanine resistance (HPRT locus) in circulating T lymphocytes from 23 Fanconi anemia (FA) patients has been determined. The glycophorin A (GPA) in vivo cell mutants assay, which detects allele loss variant phenotypes arising from mutations in erythroid progenitor cells of GPA heterozygous MN individuals, has been applied in parallel to FA patients. No significant difference in frequency of HPRT- mutants was observed in FA compared to age matched healthy donors. In contrast, the mean frequency of GPA variant cells was elevated 31-fold for hemizygous NO variants and 8-fold for homozygous NN variants in FA patients over normal controls. In heterozygous FA parents, HPRT- mutant frequencies and GPA variant frequencies were within the normal range. Molecular analysis of HPRT- mutants has previously shown that FA cells have a high tendency to form deletions. Knowing that the cellular events allowing the detection of mutations at the HPRT and the GPA locus differ, our results emphasize the possible correlation between events of spontaneous loss of heterozygosity and genetic predisposition to cancer as observed in FA.

Genotoxic effects of radiotherapy and chemotherapy on the circulating lymphocytes of breast cancer patients. III: Measurement of mutant frequency to 6-thioguanine resistance.

The mutant frequencies (MF) at the HPRT locus of peripheral blood lymphocytes collected from breast cancer patients before and after treatment according to a defined protocol of the Institut Curie were compared to those from healthy donors. The treatment involved either a local radiotherapy (RT1) followed by a chemotherapy (CT2) or a chemotherapy (CT1) followed by a radiotherapy (RT2). In accord with others, we observed no significant difference in the MF to 6-thioguanine resistance (6TG) in T lymphocytes in the control and breast cancer groups before treatment. When the effect of CT or RT either alone or in combination was analysed, the increase observed in MF can be wholly accounted for by the effect of radiation. In this study, the effect of chemotherapy on mutation did not achieve significance. Circulating T lymphocytes are mainly in the G0 phase of the cell cycle and thus would not be mutated by drugs which preferentially affect dividing cells, whereas such cells could still mutate when submitted to ionizing radiation.

Multiplicity reactivation and mutagenesis of trimethylpsoralen-damaged herpes virus in normal and Fanconi's anaemia cells.

Fanconi's anaemia (FA) cells are hypersensitive to the lethal effect of DNA cross-linking compounds. Herpes simplex virus (HSV) has been used here as a probe to monitor in FA cells repair of psoralen damage of which cross-links are a part. The replication of HSV is impaired when its DNA contains covalently photobound psoralen molecules. In comparison to other psoralens, 4,5',8-trimethylpsoralen (4,5',8-TMP) is one of the most photoreactive psoralens and it forms a relatively high proportion of DNA interstrand cross-links. TMP-damaged HSV is efficiently reactivated by multiple infection in human fibroblasts. The extent of multiplicity reactivation is greater in cells from FA donors (five strains tested) than in normal cells (three strains). Mutagenesis studied in the viral thymidine kinase locus revealed that: (i) spontaneous viral mutation rate is lower in FA than in normal cells; and (ii) under conditions of multiple infection, the mutation rate is either greater (normal cells) or unchanged (FA cells) in the progeny from psoralen-damaged HSV compared to that from untreated virus. Taken together, these observations suggest that the pathway underlying multiplicity reactivation of psoralen-damaged HSV is error-free in FA cells relative to normal cells.