Chromosome rearrangements associated with CAD gene amplification. Experiments with cell hybrids.

Resistance to phosphonacetyl-L-aspartate (PALA) is caused by CAD gene amplification. The marker chromosome of a PALA-resistant cell line containing a homogeneously staining region with amplified CAD gene was introduced into PALA-sensitive Chinese hamster cells by microcell-mediated chromosome transfer. Two monochromosomal hybrids containing the marker chromosome in addition to the normal chromosome complement of sensitive cells and 1 tetraploid hybrid containing the complete genomes of donor (resistant) and recipient (sensitive) cells were studied in detail. It was shown that (i) the presence of the marker chromosome was both a necessary and a sufficient condition for the expression of the PALA-resistant phenotype; (ii) the marker chromosome underwent rearrangements in the monochromosomal hybrids, with preferential loss of non-amplified chromosomal regions, while it was not rearranged in the tetraploid hybrid; (iii) unlike the original PALA-resistant cells obtained after long-term selection in the presence of PALA, the PALA-resistant hybrids did not show chromosomal aberrations of other than the marker chromosome. This result indicates that chromosomal aberrations may be due to the selective procedure and is not an inherent property of cells containing amplified genes.     

Effects of 3-aminobenzamide on Chinese hamster cells treated with thymidine analogues and DNA-damaging agents. Chromosomal aberrations, mutations and cell-cycle progression

The nuclear enzyme, poly(ADP-ribose) synthetase is involved in the repair of damaged DNA. We report here the results obtained with 3-aminobenzamide (3AB), an inhibitor of this enzyme, on induced biological effects. 3AB increases the frequency of chromosomal aberrations induced by DMS, EMS, ENU, bleomycin and CldUrd. The magnitude of the effect is dependent on the type of chemical used, the combinations with DMS and EMS being the most potent ones. No potentiation was observed after treatment of cells with MMC. Mutation frequencies were determined on the HPRT locus and showed that 3AB did not increase the frequency of gene mutations induced by EMS, ENU and CldUrd. Cell-cycle progression is affected when cells are grown in medium containing CldUrd and 3AB, primarily when the inhibitor is present during the second cell cycle when substituted DNA becomes replicated. The extent of the effect depends on the amount of analogue incorporated and is independent of the presence of the analogue in the medium during the second cell cycle. Analysis of chromosomal aberrations in delayed G2 cells with the aid of the premature chromosome-condensation technique revealed numerous aberrations after incorporation of CldUrd and treatment with 3AB.     

Cytogenetical characterization of Chinese hamster ovary X-ray-sensitive mutant cells, xrs 5 and xrs 6. IV. Study of chromosomal aberrations and sister-chromatid exchanges by restriction endonucleases and inhibitors of DNA topoisomerase II

Induction of chromosomal aberrations and sister-chromatid exchanges (SCEs) was studied in wild-type Chinese hamster ovary (CHO-K1) cells and its 2 X-ray-sensitive mutants xrs 5 and xrs 6 (known to be deficient in repair of DNA double-strand breaks (DSBs] by restriction endonucleases (REs) and inhibitors of DNA topoisomerase II known to induce DNA strand breaks. Five different types of REs, namely CfoI, EcoRI, HpaII (which induce cohesive DSBs), HaeIII and AluI (which induce blunt DSBs) were employed. REs that induce blunt-end DNA DSBs were found to be more efficient in inducing chromosomal aberrations than those inducing cohesive breaks. xrs 5 and xrs 6 mutants responded with higher sensitivity (50-100% increase in the frequency of aberrations per aberrant cell) to these REs than wild-type CHO-K1 cells. All these REs were also tested for their ability to induce SCEs. The frequency of SCEs increased in wild-type as well as mutant CHO cells, the induced frequency being about 2-fold higher in xrs mutants than in the wild-type cells. We also studied the effect of inhibitors of DNA topoisomerase II, namely 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) and etoposid (VP 16), at different stages of the cell cycle of these 3 types of cells. Both drugs increased the frequency of chromosomal aberrations in G2 cells. The mutants showed increased sensitivity to m-AMSA and VP 16, xrs 6 cells being 10- and 2-fold more sensitive than wild-type CHO-K1 cells respectively, and xrs 5 responding with 2-fold higher sensitivity than xrs 6 cells. G1 treatment of CHO cells with m-AMSA increased both chromosome- and chromatid-type aberrations, xrs mutants being about 3-fold more sensitive than CHO-K1 cells. The frequency of SCEs increased also after treatment of exponentially growing and S-phase CHO cells with m-AMSA and the higher sensitivity of xrs mutants (2-fold) was evident. The S-phase appeared to be a specific stage which is most prone for the induction of SCEs by m-AMSA. The results indicate that DNA DSBs induced by REs and inhibitors of DNA topoisomerase II correlate closely with induced chromosomal aberrations and SCEs in these cell lines, indicating that DSBs are responsible for the production of these 2 genetic endpoints.     

Cytological characterization of Chinese hamster ovary X-ray-sensitive mutant cells xrs 5 and xrs 6. I. Induction of chromosomal aberrations by X-irradiation and its modulation with 3-aminobenzamide and caffeine

We have studied two X-ray-sensitive mutants xrs 5 and xrs 6 (derived from the CHO-K1 cell line), known to be defective in repair of double-strand breaks, for cell killing and frequency of the chromosomal aberrations induced by X-irradiation. The survival experiments showed that mutants are very sensitive to X-rays, the D0, for the wild-type CHO-K1 was 6-fold higher than D0 value for the mutants. The modal number of chromosomes (2 n = 23) and the frequency of spontaneously occurring chromosomal aberrations were similar in all 3 cell lines. X-Irradiation of synchronized mutant cells in G1-phase significantly induced both chromosome- and chromatid-type of aberrations. The frequency of aberrations in xrs mutants was 12-fold more than in the wild-type CHO-K1 cells. X-Irradiation of G2-phase cells also yielded higher frequency of aberrations in the mutants, namely 7-8-fold in xrs 5 and about 3.5-fold in xrs 6 compared to the wild-type CHO-K1 cells. There was a good correlation between relative inability to repair of DNA double-strand breaks and induction of aberrations. The effect of 3-aminobenzamide (3AB), an inhibitor of poly(ADP-ribose) synthetase on the frequency of X-ray-induced chromosomal aberrations in these 3 cell lines was also studied. 3AB potentiated the frequency of aberrations in G1 and G2 in all the cell types. In the mutants, 3AB had a potentiating effect on the frequency of X-ray-induced chromosomal aberrations only at low doses. X-Ray-induced G2 arrest and its release by caffeine was studied by cytofluorometric methods. The relative speed with which irradiated S-G2 cells progressed into mitosis in the presence of caffeine was CHO-K1 greater than xrs 5 greater than xrs 6. Caffeine could counteract G2 delay induced by X-rays in CHO-K1 and xrs 5 but not in xrs 6. Large differences in potentiation by caffeine were observed among these cells subjected to X-rays and caffeine post-treatment for different durations. These responses and possible reasons for the increased radiosensitivity of xrs mutants are discussed and compared to ataxia telangiectasia (A-T) cells and a radiosensitive mutant mouse lymphoma cell line.     

Influence of incorporated bromodeoxyuridine on the induction of chromosomal alterations by ionizing radiation and long-wave UV in CHO cells

Incorporation of BrdUrd into nuclear DNA sensitizes CHO cells (1) to the induction of chromosomal aberrations by X-rays and 0.5 MeV neutrons and (2) to induction of chromosomal aberrations and SCEs by lw-UV. We have attempted to establish a correlation between induced chromosomal alterations and induced single- or double-strand breaks in DNA. The data show that while DSBs correlate very well with X-ray-induced aberrations, no clear correlation could be established between lw-UV induced SSBs (including alkali-labile sites) and chromosomal alterations.

In addition the effect of 3-aminobenzamide (3AB) on the induction of chromosomal aberrations and SCEs induced by lw-UV has been determined. It is shown that 3AB is without any effect when lw-UV-irradiated cells are posttreated with this inhibitor.

The significance of these results is discussed.     

Modulation of restriction enzyme-induced damage by chemicals that interfere with cellular responses to DNA damage: a cytogenetic and pulsed-field gel analysis

The electroporation of restriction enzymes into mammalian cells results in DNA double-strand breaks that can lead to chromosome aberrations. Four chemicals known to interfere with cellular responses to DNA damage were investigated for their effects on chromosome aberrations induced by AluI and Sau3AI; in addition, the number of DNA double-strand breaks at various times after enzyme treatment was determined by pulsed-field gel electrophoresis (PFGE). The poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide (3AB) dramatically increased the yield of exchanges and deletions and caused a small but transitory increase in the yield of double-strand breaks induced by the enzymes. 1-beta-D-Arabinofuranosylcytosine, which can inhibit DNA repair either by direct action on DNA polymerases alpha and delta or by incorporation into DNA, potentiated aberration induction but to a lesser extent than 3AB and did not affect the amount of DNA double-strand breakage. Aphidicolin, which inhibits polymerases alpha and delta, had no effect on AluI-induced aberrations but did increase the aberration yield induced by Sau3AI. The postreplication repair inhibitor caffeine had no effect on aberration yields induced by either enzyme. Neither aphidicolin nor caffeine modulated the amount of DNA double-strand breakage as measured by PFGE. These data implicate poly(ADP-ribosyl)ation and polymerases alpha and delta as important components of the cellular processes required for the normal repair of DNA double-strand breaks with blunt or cohesive ends. Comparison of these data with the effect of inhibitors on the frequency of X-ray-induced aberrations leads us to the conclusion that X-ray-induced aberrations can result from the misjoining or nonrejoining of double-strand breaks, particularly breaks with cohesive ends, but that this process accounts for only a portion of the induced aberrations.     

Enhanced gene amplification in human cells knocked down for DNA-PKcs

Gene amplification, a key mechanism for oncogene activation and drug resistance in tumour cells, involves the generation and joining of DNA double-strand breaks. Amplified DNA can be carried either on intra-chromosomal arrays or on extra-chromosomal elements (double minutes). We previously showed that, in rodent cells deficient in DNA-PKcs, intra-chromosomal amplification is significantly enhanced. In the present work, we studied gene amplification in human HeLa cell lines in which the expression of the DNA-PKcs gene was constitutively inhibited by shRNAs. These cell lines showed an increased sensitivity to ionizing radiations, an enhanced frequency of chromosomal aberrations and an increased rate of occurrence of methotrexate resistant colonies compared to the control cell lines (6-18 times). The main mechanism of resistance to methotrexate was extra-chromosomal amplification of the dihydrofolate reductase gene. These results indicate that, in human cells, inhibition of DNA-PKcs gene expression favours gene amplification occurring via the production of double minutes. In addition, they show that cell lines constitutively expressing shRNAs are good model systems to study the role of specific functions in gene amplification.     

Evidence of gene amplification in tunicamycin-resistant Chinese hamster ovary cells

Restriction digests of genomic DNA from tunicamycin-resistant Chinese hamster ovary cells, 3E11, were probed with the yeast transferase gene, ALG7. The data presented suggest moderate amplification of the N-acetylglucosaminyl-1-phosphate transferase gene occurred in these cells, consistent with the previously observed chromosomal translocations and increased enzymatic activity. This is the first example of gene amplification as a mechanism for aberrations in N-linked glycosylation.     

Inhibition of ADP-ribosylation increases X-ray-induced chromosomal damage in mouse testis and bone-marrow cells in vivo

The effect of 3-aminobenzamide (3AB) treatment on chromosomal radiosensitivity of mouse spermatogonial stem cells and bone-marrow cells was studied using various doses of X-rays. The results show that 3AB increases the induction of reciprocal translocations in slowly cycling spermatogonia as well as the frequency of chromosomal aberrations in actively dividing bone-marrow cells. The experiments indicate that both types of tissue are suitable to study the ability of inhibitors of ADP-ribosylation to modulate chromosome-breaking damage induced by ionizing radiation in vivo.     

Cytogenetical characterisation of Chinese hamster 43-3B transferants with the amplified or non-amplified human DNA repair gene ERCC-1

A comparative study on the biological responses to different mutagens (UV, 4NQO, MMC, MMS and EMS) was made on CHO wild-type cells (CHO-9), its UV-hypersensitive mutant 43-3B, and 2 types of its transferants, i.e., one containing a few copies of the human repair gene ERCC-1 and the other having more than 100 copies of ERCC-1 (due to gene amplification). Cell survival, chromosomal aberrations and SCEs were used as biological end-points. The spontaneous frequency of chromosomal aberrations in the transferants was less than found in 43-3B mutant cells, but still 2-3 times higher than in wild-type CHO cells. The spontaneous frequency of SCEs in the transferants was less than in 43-3B and similar to that of wild-type cells. The induction of SCEs by all tested agents in transferants was similar to that found in CHO-9 cells, while the mutant is known to respond with higher frequencies. ERCC-1 also bestowed resistance to MMS and EMS on the mutant to induction of chromosomal aberrations and cell killing to levels comparable with those of the wild-type strain. On the other hand ERCC-1 could not completely regain the repair proficiency against cell killing and induction of chromosomal aberrations by UV or MMC to the wild-type level. These results suggest that the ERCC-1 corrects the repair defect in CHO mutant cells, but it is unable to rectify fully the defect; probable reasons for this are discussed. However, amplified transferants (having more than 100 copies of the ERCC-1 gene) restored the impaired repair function in 43-3B to UV-, MMC- or 4NQO-induced DNA damage better than non-amplified transferants with a few copies of the ERCC-1. This difference may be due to the high amount of gene product involved in the excision repair process in the amplified cells.     

A branching process model of gene amplification following chromosome breakage.

We have devised a mathematical model of gene amplification utilizing recent experimental observations concerning dihydrofolate reductase (DHFR) gene amplification in CHO cells. The mathematical model, based on a biological model which proposes that acentric elements are the initial intermediates in gene amplification, includes the following features: (1) initiation of amplification by chromosomal breakage to produce an acentric structure; (2) replication of acentric DNA, once per cell cycle; (3) dissociation of replicated acentric DNA; (4) unequal segregation of acentric DNA fragments to daughter cells at mitosis; (5) subsequent reintegration of acentric fragments into chromosomes. These processes are assumed to be independent for each element present in a cell at a given time. Thus, processes of unequal segregation and integration may occur in parallel, not necessarily in a unique sequence, and may be reiterated in one or multiple cell cycles. These events are described mathematically as a Galton-Watson branching process with denumerable infinity of object types. This mathematical model qualitatively and quantitatively reproduces the major elements of the dynamical behavior of DHFR genes observed experimentally. The agreement between the mathematical model and the experimental data lends credence to the biological model proposed by Windle et al. (1991), including the importance of chromosome breakage and subsequent gene deletion resulting from resection of the broken chromosome ends as initial events in gene amplification.     

Plasmid amplification-promoting sequences from the origin region of Chinese hamster dihydrofolate reductase gene do not promote position-independent chromosomal gene amplification

Initiation of DNA synthesis occurs with high frequency at oriß, a region of DNA from the amplified dihydrofolate reductase (DHFR) domain of Chinese hamster CHOC 400 cells that contains an origin of bidirectional DNA replication (OBR). Recently, sequences from DHFR oriß/OBR were shown to stimulate amplification of cis-linked plasmid DNA when transfected into murine cells. To test the role of oriß/OBR in chromosomal gene amplification, linearized plasmids containing these sequences linked to a DHFR expression cassette were introduced into DHFR- CHO DUKX cells. After selection for expression of DHFR, cell lines that contain a single integrated, unrearranged copy of the linearized expression plasmid were identified and exposed to low levels of the folate analog, methotrexate (MTX). Of seven clonal cell lines containing the vector control, three gained resistance to MTX by 5 to 15-fold amplification of the integrated marker gene. Of 16 clonal cell lines that contained oriß/OBR linked to a DHFR mini-gene, only 6 gained resistance to MTX by gene amplification. Hence, sequences from the DHFR origin region that stimulate plasmid DNA amplification do not promote amplification of an integrated marker gene in all chromosomal contexts. In addition to showing that chromosomal position has a strong influence on the frequency of gene amplification, these studies suggest that the mechanism that mediates the experiment of episomal plasmid DNA does not contribute to the early steps of chromosomal gene amplification.     

Gene amplification causes overproduction of the first three enzymes of UMP synthesis in N-(phosphonacetyl)-L-aspartate-resistant hamster cells.

Mutant Syrian hamster cells resistant to N-(phosphonacetyl)-L-aspartate (PALA), a transition state analog inhibitor of aspartate transcarbamylase, overproduce CAD, a multifunctional protein which catalyzes the first three reactions of de novo UMP biosynthesis. Increased levels of a single mRNA cause the overproduction of CAD in all PALA-resistant mutants examined thus far. A recombinant plasmid containing a 2,3-kilobase insert complementary to the 3'-proximal region of this 7.9-kilobase mRNA has been prepared and used to show that the CAD gene is amplified in each of the 10 PALA-resistant mutants examined. Rates of association of CAD sequences in DNA isolated from PALA-sensitive and PALA-resistant cells with labeled plasmid DNA indicated that the degree of amplification is approximately equal to the degree of overproduction of protein and mRNA in each mutant. The patterns of digestion of these DNAs with restriction enzymes confirmed this result and showed that the lower limit for the size of the amplified unit is 19 kilobases, much larger than the mRNA. A comparison of restriction endonuclease digests of the cloned cDNA with digests of genomic DNA indicated that part of this difference is attributable to intervening sequences in the CAD gene. A 10.2-kilobase RNA which contains CAD sequences is found in cytoplasmic fractions from some PALA-resistant mutants but not in wild type cells. Restriction patterns were analyzed by a new method in which fragments of DNA are transferred from agarose gels to diazo paper with a high efficiency which is independent of size.     

Complementation of chromosomal aberrations in AT/NBS hybrids: inadequacy of RDS as an endpoint in complementation studies with immortal NBS cells

Nijmegen breakage syndrome (NBS) and ataxia telangiectasia (AT) are rare autosomal recessive hereditary disorders characterized by radiosensitivity, chromosomal instability, immunodeficiency and proneness to cancer. Although the clinical features of both syndromes are quite distinct, the cellular characteristics are very similar. Cells from both NBS and AT patients are hypersensitive to ionizing radiation (IR), show elevated levels of chromosomal aberrations and display radioresistant DNA synthesis (RDS). The proteins defective in NBS and AT, NBS1 and ATM, respectively, are involved in the same pathway, but their exact relationship is not yet fully understood. Stumm et al. (Am. J. Hum. Genet. 60 (1997) 1246) have reported that hybrids of AT and NBS lymphoblasts were not complemented for chromosomal aberrations. In contrast, we found that X-ray-induced cell killing as well as chromosomal aberrations were complemented in proliferating NBS-1LBI/AT5BIVA hybrids, comparable to that in NBS-1LBI cells after transfer of a single human chromosome 8 providing the NBS1 gene. RDS observed in AT5BIVA cells was reduced in these hybrids to the level of that seen in immortal NBS-1LBI cells. However, the level of DNA synthesis, following ionizing radiation, in SV40 transformed wild-type cell lines was the same as in NBS-1LBI cells. Only primary wild-type cells showed stronger inhibition of DNA synthesis. In summary, these results clearly indicate that RDS cannot be used as an endpoint in functional complementation studies with immortal NBS-1LBI cells, whereas the cytogenetic assay is suitable for complementation studies with immortal AT and NBS cells.     

Mechanisms for chromosomal aberrations in mammalian cells

Experimental evidence is presented for the involvement of DNA double-strand breaks in the formation of radiation-induced chromosomal aberrations. When X-irradiated cells were post-treated with single-strand specific Neurospora crassa endonuclease (NE), the frequencies of all classes of aberration increased by about a factor 2. Under these conditions, the frequencies of DNA double-strand breaks induced by X-rays (as determined by neutral sucrose-gradient centrifugation), also increased by a factor of 2. The frequency of chromosomal aberrations induced by fast neutrons (which predominantly induce DNA double-strand breaks) was not influenced by post-treatment with NE. Inhibition of poly(ADP-ribose) polymerase, an enzyme that uses DNA with double-strand breaks as an optimal template, by 3-aminobenzamide also increased the frequencies of X-ray-induced chromosomal aberrations, which supports the idea that DNA double-strand breaks are important lesions for the production of chromosomal aberrations induced by ionizing radiation.     

DNA instability at chromosomal fragile sites in cancer

Human chromosomal fragile sites are specific genomic regions which exhibit gaps or breaks on metaphase chromosomes following conditions of partial replication stress. Fragile sites often coincide with genes that are frequently rearranged or deleted in human cancers, with over half of cancer-specific translocations containing breakpoints within fragile sites. But until recently, little direct evidence existed linking fragile site breakage to the formation of cancer-causing chromosomal aberrations. Studies have revealed that DNA breakage at fragile sites can induce formation of RET/PTC rearrangements, and deletions within the FHIT gene, resembling those observed in human tumors. These findings demonstrate the important role of fragile sites in cancer development, suggesting that a better understanding of the molecular basis of fragile site instability is crucial to insights in carcinogenesis. It is hypothesized that under conditions of replication stress, stable secondary structures form at fragile sites and stall replication fork progress, ultimately resulting in DNA breaks. A recent study examining an FRA16B fragment confirmed the formation of secondary structure and DNA polymerase stalling within this sequence in vitro, as well as reduced replication efficiency and increased instability in human cells. Polymerase stalling during synthesis of FRA16D has also been demonstrated. The ATR DNA damage checkpoint pathway plays a critical role in maintaining stability at fragile sites. Recent findings have confirmed binding of the ATR protein to three regions of FRA3B under conditions of mild replication stress. This review will discuss recent advances made in understanding the role and mechanism of fragile sites in cancer development.     

Cytological characterization of repair-deficient CHO cell line 43-3B. I. Induction of chromosomal aberrations and sister-chromatid exchanges by UV and its modulation with 3-aminobenzamide

The induction of chromosomal aberrations and sister-chromatid exchanges (SCEs) by short-wave ultraviolet (UV) and X-irradiation was studied in Chinese hamster ovary (CHO) wild-type (WT) cells and one of its UV-hypersensitive mutants, 43-3B. The results indicate that CHO 43-3B show high levels of spontaneously occurring chromosomal aberrations and SCEs; these levels are, respectively, approximately 4 and 1.7 times those found in WT CHO. Treatment with UV produced a considerable delay in the cell-cycle progression of the mutant cells compared to the WT cells. Doses of UV that had no effect on WT cells, significantly induced chromosomal alterations in the mutant in a dose-dependent manner. An approximately 5-fold increase in the induced frequencies of SCEs was obtained in 43-3B cells after UV treatment. No synergistic effect was observed with UV irradiation and the inhibitor of poly(ADP-ribose) synthetase, 3-aminobenzamide (3AB), in either cell type. The frequency of SCEs in the mutant cell lines was lower than would be expected if the effects of UV and the inhibitor were additive. X-Ray alone in G1 and in combination with 3AB in G2 did not induce increased frequencies of chromosomal aberrations in mutant cells in comparison to the WT cells.     

Concurrent Whole-Genome Haplotyping and Copy-Number Profiling of Single Cells

Methods for haplotyping and DNA copy-number typing of single cells are paramount for studying genomic heterogeneity and enabling genetic diagnosis. Before analyzing the DNA of a single cell by microarray or next-generation sequencing, a whole-genome amplification (WGA) process is required, but it substantially distorts the frequency and composition of the cell’s alleles. As a consequence, haplotyping methods suffer from error-prone discrete SNP genotypes (AA, AB, BB) and DNA copy-number profiling remains difficult because true DNA copy-number aberrations have to be discriminated from WGA artifacts. Here, we developed a single-cell genome analysis method that reconstructs genome-wide haplotype architectures as well as the copy-number and segregational origin of those haplotypes by employing phased parental genotypes and deciphering WGA-distorted SNP B-allele fractions via a process we coin haplarithmisis. We demonstrate that the method can be applied as a generic method for preimplantation genetic diagnosis on single cells biopsied from human embryos, enabling diagnosis of disease alleles genome wide as well as numerical and structural chromosomal anomalies. Moreover, meiotic segregation errors can be distinguished from mitotic ones.     

The polymorphism of DNA repair genes XRCC1, XRCC3 and the level of chromosomal aberrations in the Uranium workers

Association between the polymorphism of DNA repair genes XRCC1 Arg399ln and XRCC3 Thr241Met and the frequency of chromosomal aberrations in the uranium workers was studied. The Gln/Gln genotype of gene XRCC1 was associated with a significant increase in the number of chromosomal aberrations as compared to the corresponding homozygous wild type Arg/Arg (p < 0.05). The frequency of chromosomal aberrations in heterozygous carriers of the XRCC3gene Thr/Met was lower than in the homozygous carriers of the wild type Thr/Thr (p < 0.001).     

Cellular and genetic studies in three UV-sensitive Chinese hamster mutants

Three UV sensitive (UV^s) mutants (CHO43RO, CHO423PV, CHO30PV), characterized by different levels of reduction in their ability to perform unscheduled DNA synthesis (UDS), were analysed for spontaneous and UV-induced frequency of chromosomal aberrations and for sensitivity to alkylating agents. The baseline frequency of chromosomal aberrations was in the normal range, whereas after UV irradiation a positive correlation between the degree of UV sensitivity and the rate of chromosomal breakage was observed. Survival experiments after mutagen exposure indicated that the UV^s clones are characterized by different levels of hypersensitivity to bifunctional alkylating agents whereas the sensitivity to monofunctional alkylating agents is in the normal range. Genetic analysis performed by measuring the survival after UV in hybrids produced by fusing UV^s cells with wild-type or UV^s cells belonging to the six Chinese hamster complementation groups, indicated that the three clones carry recessive mutations and belong to c.g. 2. These findings suggest that defects in the same gene may result in different degrees of phenotypic alterations.Abbreviations CG complementation group - EMS ethyl methane sulfonate - MMS methyl methane sulfonate - MMC mitomycin C - UV ultraviolet - UDS unscheduled DNA synthesis