O6-ethylguanine carcinogenic lesions in DNA: an NMR study of O6etG.C pairing in dodecanucleotide duplexes

The pairing of O6etG with C located four base pairs in from either end of the self-complementary d(C1-G2-C3-O6etG4-A5-G6-C7-T8-C9-G10-C11-G12) duplex (designated O6etG.C 12-mer) has been investigated from an analysis of proton and phosphorus two-dimensional NMR experiments. The structural consequences of increasing the alkyl group size were elucidated from a comparative study of the pairing of O6meG4 with C9 in a related sequence (designated O6meG.C 12-mer). The NMR parameters for both O6alkG-containing dodecanucleotides are also compared with those of the control sequence containing G4.C9 base pairs (designated G.C 12-mer). The NOE cross-peaks detected in the two-dimensional NOESY spectra of the O6alkG.C 12-mer duplexes in H2O solution establish that the O6etG4/O6meG4 and C9 bases at the lesion site stack into the helix between the flanking C3.G10 and A5.T8 Watson-Crick base pairs. The amino protons of C9 at the O6alkG4-C9 lesion site resonate as an average resonance at 7.78 and 7.63 ppm in the O6etG.C 12-mer and O6meG.C 12-mer duplexes, respectively. The observed NOEs between the amino protons of C9 and the CH3 protons of O6alkG4 establish a syn orientation of the O6-alkyl group with respect to the N1 of alkylated guanine. A wobble alignment of the O6alkG4.C9 base pair stablized by two hydrogen bonds, one between the amino group of C9 and N1 of O6alkG and the other between the amino group of O6alkG and N3 of C9, is tentatively proposed on the basis of the NOEs between the amino protons of C9 at the lesion site and the imino protons of flanking Watson-Crick base pairs. The proton and phosphorus chemical shift differences between the O6etG.C 12-mer and O6meG.C 12-mer duplexes are small compared to the differences between these O6alkG-containing duplexes and the control G.C 12-mer duplex.     

O6-ethylguanine carcinogenic lesions in DNA: an NMR study of O6etG.T pairing in dodecanucleotide duplexes

High-resolution two-dimensional NMR studies are reported on the self-complementary d-(C1-G2-C3-O6etG4-A5-G6-C7-T8-T9-G10-C11-G12) duplex (designated O6etG.T 12-mer) containing two symmetrically related O6etG.T lesion sites located four base pairs in from either end of the duplex. Parallel studies were undertaken on a related sequence containing O6meG.T lesion sites (designated O6meG.T 12-mer) in order to evaluate the influence of the size of the alkyl substituent on the structure of the duplex and were undertaken on a related sequence containing G.T mismatch sites (designated G.T 12-mer duplex), which served as the control duplex. The exchangeable and nonexchangeable proton and the phosphorus nuclei have been assigned from an analysis of two-dimensional nuclear Overhauser enhancement (NOE) and correlated spectra of the O6etG.T 12-mer, O6meG.T 12-mer, and G.T 12-mer duplexes in H2O and D2O solutions. The distance connectivities observed in the NOESY spectra of the O6alkG.T 12-mer duplexes establish that the helix is right-handed and all of the bases adopt an anti conformation of the glycosidic torsion angle including the O6alkG4 and T9 bases at the lesion site. The imino proton of T9 at the O6alkG.T lesion sites resonates at 8.85 ppm in the O6etG.T 12-mer duplex and at 9.47 ppm in the O6meG.T 12-mer duplex. The large upfield shift of the T9 imino proton resonance at the O6alkG4.T9 lesion site relative to that of the same proton in the G4.T9 wobble pair (11.99 ppm) and the A4.T9 Watson-Crick pair (13.95 ppm) in related sequences establishes that the hydrogen bonding of the imino proton of T9 to O6alkG4 is either very weak or absent. The imino proton of T9 develops NOEs to the CH3 protons of the O6etG and O6meG alkyl groups across the base pair, as well as to the imino and H5 protons of the flanking C3.G10 base pair and the imino and CH3 protons of the flanking A5.T8 base pair in the O6alkG.T 12-mer duplexes. These observations establish that the O6alkG4 and T9 residues are stacked into the duplex and that the O6CH3 and O6CH2CH3 groups of O6alkG4 adopt a syn orientation with respect to the N1 of the alkylated guanine.(ABSTRACT TRUNCATED AT 400 WORDS)     

Methylation and degradation of chromatin DNA in isolated rat liver cell nuclei]

Methylation of chromatin DNA in rat liver cell nuclei incubated in a medium with [3H]CH3-S-adenosyl methionine was studied. It was shown that under the given experimental conditions DNA methylation and chromatin degradation by endogenous nuclear nuclease (nucleases) with a formation of chromatin structural subunits occur simultaneously. An analysis of methylated chromatin DNA degradation products based on a number of approaches demonstrated a predominant methylation of extra-nucleosomal DNA. The data obtained suggest that chromatin of isolated nuclei contain sites with supermethylated DNA fragments incorporating not less than 400 nucleotide pairs. These sites possess an increased sensitivity to endogenous nuclease.     

A common mechanism for repair of O6-methylguanine and O6-ethylguanine in DNA

The mutagenic effects of several ethylating and methylating agents were assessed in Encherichia coli strains that are defective in the adaptive response to alkylating agents. These mutants were either deficient in the response or expressed it constitutively. When expressed, the repair pathway removed the major mutagenic lesion produced by either methylating or ethylating agents. This lesion was almost certainly O⁶-alkylguanine produced by alkylation of DNA, and the mechanism for its removal was characterized in vitro. E. coli cells expressing the adaptive response contain relatively large amounts of a protein that transfers the methyl group from O⁶-methylguanine to one of its own cysteine residues (Olsson & Lindahl, 1980). This methyltransferase was shown to act in an analogous fashion on O⁶-ethylguanine. Incubation of ethylated DNA with purified transferase led to disappearance of the O⁶-ethylguanine residues, and S-ethylcysteine was simultaneously generated in the protein. The greater sensitivity of E. coli wild-type to ethylating than methylating agents may be explained by a slower repair of O⁶-ethylguanine than O⁶-methylguanine and also a weaker ability of ethylating agents to induce the adaptive response.     

Repair of DNA containing O6-alkylguanine.

O6-Alkylguanines, important DNA adducts formed by alkylating agents, can lead to mutations and to cell death unless repaired. The major pathway of repair involves the transfer of the alkyl group from the DNA to a cysteine acceptor site in the protein O6-alkylguanine-DNA alkyltransferase. The alkyltransferase brings about this transfer without need for cofactors and the DNA is restored completely by the action of a single protein, but the cysteine acceptor site is not regenerated and the number of O6-alkylguanines that can be repaired is equal to the number of active alkyltransferase molecules. The alkylated form of the protein is unstable in mammalian cells and is degraded rapidly. Cloning of the cDNAs for the alkyltransferase proteins from bacteria, yeast, and mammals indicates a significant similarity, particularly in the region surrounding the cysteine acceptor site. There is a major difference in the regulation of the alkyltransferase between mammalian cells and certain bacteria, where it is induced as part of the adaptive response to alkylating agents. Regulation of the content of alkyltransferase in mammalian cells differs with species and cell type and, in some cases, the level of the protein is increased by exposure to alkylating agents or X rays. A significant fraction of human tumor cell lines do not express the alkyltransferase gene and, thus, are much more sensitive to mutagenesis and killing by alkylating agents. The frequency of primary tumor cells that lack alkyltransferase protein is not yet clear. However, it is known that the level of alkyltransferase in tumors is a significant factor in resistance to both methylating agents and bifunctional chloroethylating agents. Inactivation of the alkyltransferase, which can be brought about by pretreatment with an alkylating agent or by exposure to O6-benzylguanine (a powerful nontoxic inhibitor), sensitizes tumor cells to these chemotherapeutic alkylating agents and may prove a useful therapeutic strategy.     

Specificities of human, rat and E. coli O6-methylguanine-DNA methyltransferases towards the repair of O6-methyl and O6-ethylguanine in DNA.

The behaviour of highly purified bacterial expressed rat O6-methylguanine-DNA methyltransferase (MGMT) towards the repair of CGCm6GAGCTCGCG and CGCe6GAGCTCGCG (km6G/ke6G = 1.45, where k is the second order repair rate constant determined, m6G and e6G are O6-methyl and O6-ethylguanine) is similar to that of E. coli 39kD Ada protein (km6G/ke6G = 1.6). However, the human MGMT is very different (km6G/ke6G = 163). The preferential repair of O6-ethylguanine lesion by the rat MGMT appears not to be related to the lack of the initiator methionine in the expressed protein since similar results were obtained from N-terminal Glutathione-S-transferase (GST) fused protein (GSTMGMT) which retains the methionine. The possible relationship between these findings and the differences observed in the primary amino acid sequence of these proteins is discussed. In addition the preferential repair of O6-ethylguanine substrate by the 39kD Ada protein as compared to the catalytic C-terminus alone (different by 134 times) suggests that the N-terminus plays a crucial role in the repair of O6-ethylguanine. This is in contrast to the minor effects of the GST domain when fused to the N-terminus of mammalian MGMT.     

DNA replication in isolated HeLa cell nuclei

DNA replication was investigated in HeLa cell nuclei isolated from different phases of the cell cycle. DNA synthesis occurred only in S-phase nuclei and was dependent on the presence of the four deoxynucleoside triphosphates, Mg⁺⁺, ATP and S-phase cytoplasm. G₁-phase cytoplasm was unable to support such DNA synthesis. A purified preparation of calf thymus DNA polymerase, however, was able to replace S-phase cytoplasm in supporting ATP dependent DNA synthesis, which suggests that the S-phase cytoplasmic factor is a DNA polymerase. G₁-phase nuclei could under no conditions be stimulated to initiate DNA replication prematurely.     

Repair of intrinsic DNA lesions.

The repair of apurinic/apyrimidinic (AP) sites is described. The major pathway involves hydrolysis of the stable phosphodiester bond on the 5' side of the lesion by an AP endonuclease. The 5' terminal deoxyribose-phosphate residue is excised by a separate phosphodiesterase which does not appear to be an exonuclease. Repair replication of the single missing nucleotide residue by a DNA polymerase and ligation complete the excision-repair process. The possibility that minor DNA lesions may accumulate with time in long-lived cells is considered. Such lesions should be chemically stable and should not be recognized by DNA-repair enzymes.     

DNA synthesis in HeLa cell nuclei isolated in a non-aqueous medium.

Nuclei were isolated from synchronized HeLa cells in the S-phase by a modification of the non-aqueous method described by Kirsch et al. (Science (1970) 168, 1592-1595). The method involved lyophilization of the cells, homogenization in non-aqueous glycerol and centrifugation in a gradient of 0-35% (w/w) 3-chloro-1,2-propanediol in glycerol. Such nucleic incorporated deoxyribonucleotides into DNA when incubated in an aqueous buffer containing Mg2+, ATP, dATP, dGTP, dCTP and dTTP. The product was sensitive to DNAase and banded with bulk DNA in isopycnic centrifugation. Sedimentation of the product in alkaline sucrose gradients after labelling of the nuclei for 2 min revealed labelled material in the 5 S peak and in the 18 S area. The material in the 5 S peak moved into the 12 S area after a 13 min chase.     

Heat-induced alterations in DNA polymerase activity of HeLa cells and of isolated nuclei. Relation to cell survival

The activity of DNA polymerase alpha and beta was assayed in heated HeLa S3 cells as well as in nuclei isolated from these cells. The enzyme activity as measured in cells and in nuclei has been compared with the extent of cell survival after the different hyperthermic doses. It was found that although the activity of the cellular DNA polymerases was related to cell survival after single heat doses, no correlation was found when thermotolerant cells were heated. When the activity of the DNA polymerases was determined in nuclei isolated from non-heated and heated cells, more polymerase activity was found in the nuclei of the heated cells. However, the heat sensitivity of DNA polymerase activity was the same for nuclei isolated from control, pre-heated and thermotolerant cells. Heat protection of polymerase activity by erythritol and sensitization by procaine was found when cells, but not when nuclei, were heated in the presence of these modifiers. It is concluded that (the nuclear bound) DNA polymerases are not to be considered as key enzymes in cellular heat sensitivity of HeLa S3 cells.     

DNA constancy and chromatin structure in some cell nuclei ofAmphiuma

Synopsis In a series of microspectrophotometric and microphotometric investigations, it has been found that in lymphocytes of the primitive amphibianAmphiuma the very large amount of Feulgen-DNA per nucleus (that is, the amount of DNA revealed by a Feulgen hydrolysis-Schiff technique) is constant within the limits of the measuring error. The Feulgen hydrolysis time had to be reduced considerably in order to bring down the extinctions (optical densities) of these very voluminous and densely staining nuclei. Off-peak absorption of cells in smears stained in the usual way with the Feulgen-Schiff method appeared to be of no value in these experiments. The relation between the Feulgen-DNA content of lymphocyte nuclei of human andAmphiuma cells, as determined from the slope of the hydrolysis curve, appeared to be around 124, which fits well with biochemical data from the literature.Cytologically, a large part of the chromatin appeared to exist in large clumps of heterochromatin. In marginated plaques of condensed chromatin, local areas of lower density occur and are in close association with nuclear pores. The dense lamina is often very pronounced in these nuclei.     

Enzymatic removal of O6-ethylguanine from mitochondrial DNA in rat tissues exposed to N-ethyl-N-nitrosourea in vivo

DNA repair is essential for maintaining the integrity of the genetic material, and a number of DNA repair mechanisms have been fairly well characterized for the nuclear DNA of eukaryotic cells as well as prokaryotes. However, little is known about DNA repair in mitochondria. Using highly sensitive immunoanalytical methods to detect specific DNA alkylation products, we found active removal of O6-ethyl-2'-deoxyguanosine (O6-EtdGuo) from rat liver mitochondrial DNA after pulse-exposure to N-ethyl-N-nitrosourea in vivo. In the kidney, O6-EtdGuo was removed from mitochondrial DNA with moderate efficiency, but nearly no removal was observed from the DNA of brain mitochondria. Among the rat tissues examined, the kinetics of O6-EtdGuo elimination from mitochondrial DNA was very similar to the kinetics of removal from nuclear DNA. O4-Ethyl-2'-deoxythymidine, another premutagenic DNA ethylation product, was stable in both mitochondrial and nuclear DNA of rat liver.