Visiting Professor Manjit Dosanjh

The vinyl chloride DNA derivative N2,3-ethenoguanine produces G----A transitions in Escherichia coli.

Proceedings of the National Academy of Sciences of the United States of America 88:22 (1991) 9974-9978

Authors:

KC Cheng, BD Preston, DS Cahill, MK Dosanjh, B Singer, LA Loeb

Abstract:

Vinyl chloride is a known human and rodent carcinogen that forms several cyclic base derivatives in DNA. The mutagenic potential of these derivatives has been examined in vitro but not in vivo. One of these derivatives, N2,3-ethenoguanine (epsilon G), is known to base pair with both cytosine and thymine during in vitro DNA synthesis, which would result in G----A transitions. To determine the base pairing specificity of this labile guanine derivative in Escherichia coli, we have developed a genetic reversion assay for guanine derivatives. The assay utilizes DNA polymerase-mediated analogue insertion into a bacteriophage vector, M13G*1, which detects all single-base substitutions at position 141 of the lacZ alpha gene by change in plaque color. After the insertion of a single epsilon G opposite the template cytosine at position 141 by use of epsilon dGTP and DNA polymerase and further extension with all four normal dNTPs, the DNA was transfected into E. coli. Transfection of M13G*1 containing epsilon G at the target site yielded 135 mutants among 26,500 plaques, 134 of which represented G----A transitions. The uncorrected mutation frequency was 0.5%, as compared with the control value, approximately 0.02%; when corrected for epsilon G content and penetrance, the calculated mutagenic potential of epsilon G (mutations/analogue) was about 13%. We thus conclude that epsilon G specifically induces G----A transitions during DNA replication in E. coli. The M13G*1 assay may permit the testing of other labile guanine derivatives not otherwise amenable to mutagenesis studies.

Human cells contain protein specifically binding to a single 1,N6-ethenoadenine in a DNA fragment.

Proceedings of the National Academy of Sciences of the United States of America 88:15 (1991) 6839-6842

Authors:

B Rydberg, MK Dosanjh, B Singer

Abstract:

A human DNA binding protein has been characterized from cell-free extracts of liver, placenta, and cultured cells. This protein, apparent molecular mass approximately 35 kDa, to our knowledge, does not resemble other proteins reported to bind to carcinogen-modified DNA. The probe used for characterization was a 25-base oligonucleotide containing a single site-specifically placed 1,N6-ethenoadenine (epsilon A), a product of vinyl chloride metabolism. When annealed to form an epsilon A.T or epsilon A.C pair, a strong affinity to the protein was observed, with a binding constant of approximately 1 x 10(9) M-1. In contrast, very little binding was found with an epsilon A.A pair and none was found with an epsilon A.G pair. This suggests protein recognition of a specific structural alteration. Other defined probes with alkyl adducts did not bind. In addition, the human cell extracts and a rat liver extract were found to nick specifically at the 5' side of the epsilon A adduct, which could indicate a possible associated repair activity.

Comparative mutagenesis of O6-methylguanine and O4-methylthymine in Escherichia coli.

Biochemistry 30:28 (1991) 7027-7033

Authors:

MK Dosanjh, B Singer, JM Essigmann

Abstract:

The qualitative and quantitative features of mutagenesis by two DNA adducts of carcinogenic alkylating agents, O6-methylguanine (m6G) and O4-methylthymine (m4T), were examined in vivo. The deoxyhexanucleotides 5'-GCTAGC-3' and 5'-GCTAGC-3' were synthesized, where the underlined bases are the positions of m4T or m6G, respectively. By use of recombinant DNA techniques, the respective hexanucleotides or an unmodified control were inserted into a six-base gap in the otherwise duplex genome of the Escherichia coli virus M13mp19-NheI. The duplex adducted genome was converted to single-stranded form and introduced into an E. coli strain that was phenotypically normal with regard to m6G/m4T repair, a strain deficient in repair by virtue of an insertion in the gene encoding the Ada-m6G/m4T DNA methyltransferase, or the same two cell lines after challenge with N-methyl-N'-nitro-N-nitrosoguanidine. Treatment with this alkylating agent chemically compromises alkyl-DNA repair functions. The mutation efficiency of m6G was low or undetectable (0-1.7%) in all cell systems tested, owing, we believe, to rapid repair. In striking contrast, the mutagenicity of m4T was high (12%) in cells fully competent to repair alkylation damage and was roughly doubled when those cells were pretreated with N-methyl-N'-nitro-N-nitrosoguanidine to suppress repair. Taken together, these data suggest that m4T is potentially more mutagenic than m6G and, if formed by a DNA methylating agent, may pose a significant threat to the genetic integrity of an organism.

Evidence for the mutagenic potential of the vinyl chloride induced adduct, N2, 3-etheno-deoxyguanosine, using a site-directed kinetic assay.

Carcinogenesis 12:4 (1991) 745-747

Authors:

B Singer, JT Kuśmierek, W Folkman, F Chavez, MK Dosanjh

Abstract:

N2,3-Ethenoguanine (epsilon G) is a product of vinyl chloride reaction with DNA in vivo and of its ultimate metabolite, chloroacetaldehyde, in vitro. The synthesis of the very labile 5'-triphosphate of N2,3-etheno-deoxyguanosine (epsilon dGuo) has made it possible to study the base pairing properties of this derivative placed opposite a defined normal base in a 25-base oligonucleotide template. The kinetic parameters, Km and Vmax were determined from elongation of a [32P]5'-end labeled primer annealed one base prior to the designated template base, epsilon G.T pairs, which would be mutagenic, were formed with a frequency 2- to 4-fold greater than the analogous wobble pair, G.T. The non-mutagenic pairing, epsilon G.C, occurs with a lower frequency than G.C but neither epsilon G.T or epsilon G.C constitute a significant block to replication. The frequency of epsilon G.T formation was similar with all polymerases tested: Escherichia coli DNA polymerase I (Klenow fragment), exonuclease-free Klenow, Drosophila melanogaster polymerase alpha-primase complex and human immunodeficient virus-I reverse transcriptase (HIV-RT). It is concluded that these prokaryotic and eukaryotic replicating enzymes apparently recognize the same structural features, and on replication G----A transitions would occur, which in turn, could initiate malignant transformation. In contrast to the G.T mismatch which is known to have a specific repair system, etheno derivatives are apparently not repaired in vivo.

Relative efficiencies of the bacterial, yeast, and human DNA methyltransferases for the repair of O6-methylguanine and O4-methylthymine. Suggestive evidence for O4-methylthymine repair by eukaryotic methyltransferases.

The Journal of biological chemistry 266:5 (1991) 2767-2771

Authors:

M Sassanfar, MK Dosanjh, JM Essigmann, L Samson

Abstract:

The suicidal inactivation mechanism of DNA repair methyltransferases (MTases) was exploited to measure the relative efficiencies with which the Escherichia coli, human, and Saccharomyces cerevisiae DNA MTases repair O6-methylguanine (O6MeG) and O4-methylthymine (O4MeT), two of the DNA lesions produced by mutagenic and carcinogenic alkylating agents. Using chemically synthesized double-stranded 25-base pair oligodeoxynucleotides containing a single O6MeG or a single O4MeT, the concentration of O6MeG or O4MeT substrate that produced 50% inactivation (IC50) was determined for each of four MTases. The E. coli ogt gene product had a relatively high affinity for the O6MeG substrate (IC50 8.1 nM) but had an even higher affinity for the O4MeT substrate (IC50 3 nM). By contrast, the E. coli Ada MTase displayed a striking preference for O6MeG (IC50 1.25 nM) as compared to O4MeT (IC50 27.5 nM). Both the human and the yeast DNA MTases were efficiently inactivated upon incubation with the O6MeG-containing oligomer (IC50 values of 1.5 and 1.3 nM, respectively). Surprisingly, the human and yeast MTases were also inactivated by the O4MeT-containing oligomer albeit at IC50 values of 29.5 and 44 nM, respectively. This result suggests that O4MeT lesions can be recognized in this substrate by eukaryotic DNA MTases but the exact biochemical mechanism of methyltransferase inactivation remains to be determined.