Enhancement by caffeine of N-methyl-N-nitrosourea-induced mutations and chromosome aberrations in Chinese hamster cells

N-Methyl-N-nitrosourea (MNU) increased the induction of mutations to 8-azaguanine resistance in Chinese hamster cells in a dose-dependent manner. Mutations were only observed with toxic concentrations of MNU. Since a plot of the fraction of cells surviving alkylation against the extent of methylation of DNA exhibited a shoulder it followed that there was a threshold level of DNA reaction which did not lead to mutations possibly due to efficient repair of DNA damage. Post-alkylation incubation in medium containing caffeine decreased cell survival while at the same time it increased the induced mutation frequency. Mutation frequency was increased whether caffeine was present for 48 h or for a further 12 days in the presence of the selective agent 8-azaguanine. MNU caused chromatid aberrations in Chinese hamster cells and these reached a value of 15% of the treated cells by 48 h after methylation. Post-alkylation incubation in caffeine increased the percentage of cells showing chromosomal damage to a maximum of 86% of treated cells by 40 h after alkylation. A large proportion of cells exhibited completely fragmented or shattered chromosomes. The proportion of cells showing the presence of micronuclei also dramatically increased following incubation of methylated cells in caffeine. These results are discussed in terms of the possibility that damage to DNA is responsible for the lethal, mutagenic and cytological effects of MNU in Chinese hamster cells, and that there is a caffeine sensitive step(s) in the repair of the DNA damage which is responsible for these effects.     

Non-phenotypic selection of N-methyl-N'-nitro-N-nitrosoguanidine-directed mutation at a predicted hotspot site

The striking mutational specificity of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) exhibited in the lacI gene in Escherichia coli allows comment on the phenotypic consequences of mutation at specific sequences that are not recovered after MNNG mutagenesis. We predict that the I+ phenotype is maintained when such silent positions are substituted by amino acids whose codons are generated by the MNNG-directed G:C----A:T transition. We chose the mutationally silent Gly200 codon (an MNNG hotspot motif sequence) to test this prediction. Through MNNG mutagenesis we have generated, identified and isolated a G:C----A:T transition at position 627 (5'-G-G-C-3') under non-selective conditions which creates the Gly200----Asp substitution. The I+ phenotype is retained for this altered repressor.     

Fidelity of replication of the leading and the lagging DNA strands opposite N-methyl-N-nitrosourea-induced DNA damage in human cells.

Semi-conservative replication of double-stranded DNA in eukaryotic cells is an asymmetric process involving leading and lagging strand synthesis and different DNA polymerases. We report a study to analyze the effect of these asymmetries when the replication machinery encounters alkylation-induced DNA adducts. The model system is an EBV-derived shuttle vector which replicates in synchrony with the host human cells and carries as marker gene the bacterial gpt gene. A preferential distribution of N-methyl-N-nitrosourea (MNU)-induced mutations in the non transcribed DNA strand of the shuttle vector pF1-EBV was previously reported. The hypermutated strand was the leading strand. To test whether the different fidelity of DNA polymerases synthesizing the leading and the lagging strands might contribute to MNU-induced mutation distribution the mutagenesis study was repeated on the shuttle vector pTF-EBV which contains the gpt gene in the inverted orientation. We show that the base substitution error rates on an alkylated substrate are similar for the replication of the leading and lagging strands. Moreover, we present evidence that the fidelity of replication opposite O6-methylguanine adducts of both the leading and lagging strands is not affected by the 3' flanking base. The preferential targeting of mutations after replication of alkylated DNA is mainly driven by the base at the 5' side of the G residues.     

Correction of chromosomal point mutations in human cells with bifunctional oligonucleotides.

A sequence-specific genomic delivery system for the correction of chromosomal mutations was designed by incorporating two different binding domains into a single-stranded oligonucleotide. A repair domain (RD) contained the native sequence of the target region. A third strand-forming domain (TFD) was designed to form a triplex by Hoogsteen interactions. The design was based upon the premise that the RD will rapidly form a heteroduplex that is anchored synergistically by the TFD. Deoxyoligonucleotides were designed to form triplexes in the human adenosine deaminase (ADA) and p53 genes adjacent to known point mutations. Transfection of ADA-deficient human lymphocytes corrected the mutant sequence in 1-2% of cells. Neither the RD or TFD individually corrected the mutation. Transfection of p53 mutant human glioblastoma cells corrected the mutation and induced apoptosis in 7.5% of cells.     

Metabolic selection of glycosylation defects in human cells

Changes in glycosylation are often associated with disease progression, but the genetic and metabolic basis of these events is rarely understood in detail at a molecular level. We describe a metabolism-based approach to the selection of mutants in glycoconjugate biosynthesis that provides insight into regulatory mechanisms for oligosaccharide expression and metabolic flux. Unnatural intermediates are used to challenge a specific pathway, and cell surface expression of their metabolic products provides a readout of flux in that pathway and a basis for selecting genetic mutants. The approach was applied to the sialic acid metabolic pathway in human cells, yielding novel mutants with phenotypes related to the inborn metabolic defect sialuria and metastatic tumor cells.     

Rescue of nonsense mutations by amlexanox in human cells

ABSTRACT: BACKGROUND: Nonsense mutations are at the origin of many cancers and inherited genetic diseases. The consequence of nonsense mutations is often the absence of mutant gene expression due to the activation of an mRNA surveillance mechanism called nonsense-mediated mRNA decay (NMD). Strategies to rescue the expression of nonsense-containing mRNAs have been developed such as NMD inhibition or nonsense mutation readthrough. METHODS: Using a dedicated screening system, we sought molecules capable to block NMD. Additionally, 3 cell lines derived from patient cells and harboring a nonsense mutation were used to study the effect of the selected molecule on the level of nonsense-containing mRNAs and the synthesis of proteins from these mutant mRNAs. RESULTS: We demonstrate here that amlexanox, a drug used for decades, not only induces an increase in nonsense-containing mRNAs amount in treated cells, but also leads to the synthesis of the full-length protein in an efficient manner. We also demonstrated that these full length proteins are functional. CONCLUSIONS: As a result of this dual activity, amlexanox may be useful as a therapeutic approach for diseases caused by nonsense mutations.     

Allelic losses in mutations at the aprt locus of human lymphoblastoid cells.

We analyzed the nature of mutations at the autosomal locus coding for adenine phosphoribosyltransferase (aprt) in human cells to elucidate the process(es) governing mutagenesis at autosomal loci. A human lymphoblastoid cell line, WR10, was found to be heterozygous for mutated allele at the aprt locus, and was used for mutation analyses. By the use of a restriction fragment length polymorphism associated with the aprt locus in WR10 cells, the molecular characteristics of mutations arising spontaneously or induced by gamma-rays were investigated. Eighty-five percent (22/26) of the spontaneous mutant clones and 93% (64/69) of the gamma-ray-induced mutant clones resulted from loss of one of the two aprt alleles. Determination of the dosage of aprt genes in those mutants with allelic losses revealed that approximately half of them retained two copies of the mutated allele. These data suggest that the mutational events leading to APRT deficiency are analogous to those reported for tumor suppressor genes in malignancies.     

Radiation-induced specific locus mutations in human mammary epithelial cells

A specific locus mutagenesis assay using primary cultures of human mammary epithelial cells has been developed. A mutation frequency at the hypoxanthine-guanine phosphoribosyl transferase (HGPRT) locus of approximately 2 X 10(-5) mutations per surviving cell per gray of ionizing radiation was estimated in these cells.     

Genetic selection of activatory mutations in KcsA

The KcsA potassium channel from Streptomyces lividans is one of the most actively studied ion channels. However, there are still unresolved issues about its gating mechanism in vivo because the channel is only activated by highly acidic intracellular pH, meaning that it will be mostly inactive in its host environment. In this study we have used a genetic complementation assay of K+-auxotrophic E.coli (TK2420) and S.cerevisiae (SGY1528) to identify activatory or 'gain-of-function' mutations which allow functional activity of KcsA in the physiological environment of two markedly different expression systems. These mutations clustered at the helix-bundle-crossing in both TM1 and TM2 (residues H25, L105, A108, T112, W113, F114, E118 & Q119), and include residues previously implicated in the pH-gating mechanism. We discuss how these gain-of-function mutations may result in their activatory phenotype, the relative merits of the E.coli and S.cerevisiae genetic complementation approaches for the identification of gating mutations in prokaryotic K+ channels, and ways in which this assay may be improved for future use in screening protocols.     

Genetic selection of activatory mutations in KcsA

The KcsA potassium channel from Streptomyces lividans is one of the most actively studied ion channels. However, there are still unresolved issues about its gating mechanism in vivo because the channel is only activated by highly acidic intracellular pH, meaning that it will be mostly inactive in its host environment. In this study we have used a genetic complementation assay of K+-auxotrophic E. coli (TK2420) and S. cerevisiae (SGY1528) to identify activatory or 'gain-of-function' mutations which allow functional activity of KcsA in the physiological environment of two markedly different expression systems. These mutations clustered at the helix-bundle-crossing in both TM1 and TM2 (residues H25, L105, A108, T112, W113, F114, E118 and Q119), and include residues previously implicated in the pH-gating mechanism. We discuss how these gain-of-function mutations may result in their activatory phenotype, the relative merits of the E. coli and S. cerevisiae genetic complementation approaches for the identification of gating mutations in prokaryotic K+ channels, and ways in which this assay may be improved for future use in screening protocols.     

Reduction in the frequency of N-methyl-N-nitrosourea-induced somatic mutations in Tradescantia by pretreatment with low doses of alkylating agents

Treatment of Tradescantia cuttings with sub-mutagenic doses of N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea and methyl methanesulphonate before challenging doses of MNU reduced the frequency of somatic mutations in stamen hairs as compared with the effect of challenging dose alone. The highest response was about a 50% reduction in the mutagenic effect of the challenge dose.     

Paraquat-mediated selection for mutations in the manganese-superoxide dismutase gene sodA.

We report the unexpected result that Escherichia coli isolates containing a multicopy plasmid (pDT1.5) carrying the manganese-superoxide dismutase gene sodA were more sensitive than the wild type to paraquat-mediated growth inhibition. The pDT1.5 locus responsible for the paraquat-sensitive phenotype was delimited to a 0.6-kilobase segment by transposon Tn5 mutagenesis. Moreover, superoxide dismutase activity was the same as in the wild type in strains carrying pDT1.5::Tn5 insertions mapping to the 0.6-kilobase locus. These data identify the 0.6-kilobase segment as the locus of sodA and establish an association between growth inhibition by paraquat and the function of the plasmid-borne sodA gene.     

Estimating selection on nonsynonymous mutations

The distribution of mutational effects on fitness is of fundamental importance for many aspects of evolution. We develop two methods for characterizing the fitness effects of deleterious, nonsynonymous mutations, using polymorphism data from two related species. These methods also provide estimates of the proportion of amino acid substitutions that are selectively favorable, when combined with data on between-species sequence divergence. The methods are applicable to species with different effective population sizes, but that share the same distribution of mutational effects. The first, simpler, method assumes that diversity for all nonneutral mutations is given by the value under mutation-selection balance, while the second method allows for stronger effects of genetic drift and yields estimates of the parameters of the probability distribution of mutational effects. We apply these methods to data on populations of Drosophila miranda and D. pseudoobscura and find evidence for the presence of deleterious nonsynonymous mutations, mostly with small heterozygous selection coefficients (a mean of the order of 10(-5) for segregating variants). A leptokurtic gamma distribution of mutational effects with a shape parameter between 0.1 and 1 can explain observed diversities, in the absence of a separate class of completely neutral nonsynonymous mutations. We also describe a simple approximate method for estimating the harmonic mean selection coefficient from diversity data on a single species.     

Analysis of point mutations induced by ultraviolet light in human cells

Mutations induced in cultured human cells by 254-nm UV light were analyzed within exon 3 of the hypoxanthine guanine phosphoribosyl transferase (HPRT) gene. Five large independent cultures of human lymphoblastoid cells, line TK6, were exposed to 4 J/m2 of 254-nm UV light and mutants at the HPRT locus were selected en masse by 6-thioguanine (6TG) resistance. Exon 3 of the HPRT gene was amplified from the mutant cells by polymerase chain reaction (PCR) using modified T7 DNA polymerase. Denaturing gradient gel electrophoresis (DGGE) was used to separate the mutant sequences from the wild type as mutant/wild-type heteroduplexes. Individual mutant bands were isolated from the gel and the nature of the mutations was determined by direct sequencing. Eight predominant mutations were detected in the 184-bp exon 3 sequence. Of these, 3 transition, including 2 G-C to A-T and 1 A-T to G-C and 2 A-T to C-G transversions, appeared in all 5 UV-treated cultures but not in untreated cultures and were thus considered to be mutational hotspots. These observations are similar in nature to those previously reported in bacterial and rodent cells. A single G deletion, a tandem substitution of CpT for TpA, and a tandem triple substitution of GpGpA for ApApG were also observed but in only 2, 2 and 3 of the 5 UV-treated cultures, respectively. Numerical analysis of the mutant fractions of these 8 mutations indicated that each of them was distributed as a set of non-random and independent events, i.e., a mutational hotspot.     

Induction of HLA mutations by chemical mutagens in human lymphoid cells

We studied the effects of mutagens on the frequency of HLA loss variants in the diploid human lymphoid cell line T5-1, as well as the stability of mutagen-induced variants and the extent of the genetic lesions induced. Mutagens used were of different types, and included ethyl methanesulfonate (EMS), ICR-191 (ICR), and mitomycin C. Variant frequency was determined seven days after a 24-hour exposure to mutagen, by which time the cloning efficiency of exposed cultures, which was reduced following mutagenesis, had returned to normal. ICR and EMS induced dose-related increases in variant frequency of greater than two orders of magnitude at the highest concentrations tested. Mitomycin C increased variant frequency by tenfold at the one concentration tested. Seventeen of 18 induced variants showed persistence of the variant phenotype during prolonged culture following isolation. Genetic lesions induced by ICR and EMS did not extend as far as the distance between theHLA-A and -B loci (0.8 map units) in any of 21 clones tested. These data suggest a mutational origin for most mutagen-induced HLA variants of diploid cells (except for some induced by mitomycin C). Mutagenesis and mutational analysis are promising probes for studies of theHLA region.Abbreviations used in this paper are as follows MHC major histocompatibility complex - EMS ethyl methanesulfonate - ICR ICR-191 - C complement