Benzpyrene groups bind preferentially to the DNA of active chromatin in human lung cells.

The cells of the bronchial epithelium of man are targets for benzo(a)pyrene carcinogenesis. When cultures of these cells, and of non-target fibroblasts, are exposed to [3H]-benzo(a)pyrene, we find that the epithelial cells metabolise and bind to DNA far greater amounts of benzpyrene than do fibroblasts. By analysis of nuclei of benzpyrene-treated cells for sensitivity to limited digestion with pancreatic DNase I, we have shown that benzpyrene groups bind initially to the DNA of expressed (DNase I sensitive) regions of chromatin in both cell types. Covalent binding of benzpyrene groups to non-expressed (DNase I resistant) regions follows rapidly in the target epithelial cells. These maintain high levels of carcinogen adducts in their DNA. In fibroblasts, benzpyrene group binding to non-expressed DNA occurs more slowly and active removal of adducts from the DNA is evident.     

Occurrence of NI and NII type protein kinases in the nuclei from various tissues of the rat

Cyclic nucleotide-independent protein kinases that preferentially phosphorylated casein and phosvitin as substrate were surveyed in various tissue nuclei of the rat. Enzymes were extracted from the isolated nuclei of liver, kidney, spleen, brain, heart, or testis tissue with a buffer solution containing 0.4 m NaCl, and analyzed by DEAE-Sephadex, phosphocellulose, and Bio-Gel A-1.5m column chromatographies. The chromatographic study together with characterization of the enzymes demonstrated that all the tissues contained in their cell nuclei commonly two protein kinases, the NI and NII types, and that these were exclusively found as main nuclear casein kinases. NII enzyme activity was stimulated by polyamines and strongly inhibited by heparin. By contrast, the NI enzymes were little influenced by these compounds. We interpret the present results as suggesting that NI and NII type protein kinases may be found in the cell nuclei from many tissues of rat, and have distinct functions in the cell nuclei.     

Differential effects of N-acetyl-2-aminofluorene and N-2-aminofluorene adducts on the conformational change in the structure of DNA polymerase I (Klenow fragment)

The carcinogen N-acetyl-2-aminofluorene forms two major DNA adducts: the N-(2'-deoxyguanosin-8-yl)-2-acetylaminofluorene adduct (dG-C8-AAF) and its deacetylated derivative, the N-(2'-deoxyguanosin-8-yl)-2-aminofluorene adduct (dG-C8-AF). It is well established that the AAF adduct is a very strong block for DNA synthesis in vitro while the AF adduct is more easily bypassed. In an effort to understand the molecular mechanism of this phenomenon, the structure of the complex of an exonuclease-deficient Escherichia coli DNA polymerase I (Klenow fragment) bound to primer-templates containing either an AF or AAF adduct in or near the active site was probed by nuclease and protease digestion analyses. The results of these experiments suggest that positioning the AAF adduct in the polymerase active site strongly inhibits the conformational change that is required for the insertion of a nucleotide. Similar experiments with AF-modified primer-templates shows a much less pronounced effect. The inhibition of the conformational change by either adduct is not detected if they are positioned in the single-stranded part of the template just one nucleotide before the active site. These findings may explain the different abilities of these lesions to block DNA synthesis.     

Metabolism and nucleic acid binding of 7-fluoro-2-acetamidofluorene in rats: oxidative defluorination and apparent dissociation from hepatocarcinogenesis of 8-(N-arylamide) guanine adducts on DNA

The significance in hepatocarcinogenesis of various arylamine/amide adducts with nucleic acid was investigated by the use of comparison studies on several different parameters. Female Fischer and Sprague-Dawley rats are comparably sensitive to hepatocarcinogenesis by 2-acetamidofluorene (AAF), while male rats are more sensitive. 7-Fluoro-AAF is more carcinogenic in Sprague-Dawley rats than is AAF, but is strikingly so toward the liver of the female rat. Based on these observations, binding of both compounds to liver nucleic acids was determined for male and female Fischer rats at 1 and 3 days after a single injection of carcinogen, and in female Sprague-Dawley rats from 1 to 28 days after a single injection. As shown by others, no 8-(N-2-fluorenylacetamido)guanine adduct could be found in RNA or DNA of female Sprague-Dawley rats treated with AAF (nor was the corresponding 7-fluoro derivative detectable). These adducts were present, however, in comparable amounts in both male and female Fischer rats. The binding of 7-fluoro-AAF derivatives was higher than that of AAF derivatives in female Sprague-Dawley rats. Feeding of either AAF or 7-fluoro-AAF to Sprague-Dawley rats for 4 weeks before a single injection of [3H]7-fluoro-AAF resulted in reduction of the 8-(N-2-(7-fluoro)fluorenylacetamido)guanine adduct in males to undetectable levels in DNA and to 10% of control level in RNA. Non-acetylated adducts were increased in males, but decreased in females by AAF prefeeding; 7-fluoro-AAF prefeeding resulted in little change in adduct formation in females and in a major increase in non-acetylated adducts in males. AAF adducts disappeared from DNA more rapidly than did 7-fluoro-AAF adducts. Assay of the urinary metabolites from the animals in the prefeeding experiment showed that all compounds fed (including the non-hepatocarcinogens 4-acetamidobiphenyl and 2-acetamidophenanthrene) increased the proportion of N-hydroxy-7-fluoro-AAF among the metabolites. Defluorination of 7-fluoro-AAF to 7-hydroxy-AAF was also demonstrated and the ratio of 7-hydroxy-AAF to 5-hydroxy-7-fluoro-AAF was comparable to that observed for 7-hydroxy-AAF/5-hydroxy-AAF and AAF itself, suggesting that fluoro substitution does not increase activity by preventing detoxication.     

Alternative conformations of DNA modified by N-2-acetylaminofluorene

Modification of DNA by the carcinogen N-acetoxy-N-2-acetylaminofluorene gives two adducts, a major one at the C-8 position of guanine and a minor one at the N-2 position with differing conformations. Binding at the C-8 position results in a large distortion of the DNA helix referred to as the “base displacement model” with the carcinogen inserted into the DNA helix and the guanosine displaced to the outside. The result is increased susceptibility to nuclease S, digestion due to the presence of large, single-stranded regions in the modified DNA. In contrast, the N-2 adduct results in much less distortion of the helix and is less susceptible to nuclease S₁ digestion. A third and predominant adduct is formed in vivo, the deacetylated C-8 guanine adduct. The conformation of this adduct has been investigated using the dimer dApdG as a model for DNA. The attachment of aminofluorene (AF) residues introduced smaller changes in the circular dichroism (CD) spectra of dApdG than binding of acetylaminofluorene (AAF) residues. Similarly, binding of AF residues caused lower upfield shifts for the H-2 and H-8 protons of adenine than the AAF residues. These results suggest that AF residues are less stacked with neighboring bases than AAF and induce less distortion in conformation of the modified regions than AAF. An alternative conformation of AAF-modified deoxyguanosine has been suggested based on studies of poly(dG-dC)·poly(dG-dC). Modification of this copolymer with AAF to an extent of 28% showed a CD spectrum that had the characteristics of the left-handed Z conformation seen in unmodified poly-(dG-dC)·poly(dG-dC) at high ethanol or salt concentrations. Poly(dG)·poly(dC), which docs not undergo the B to Z transition at high ethanol concentrations, did not show this type of conformational change with high AAF modification. Differences in conformation were suggested by single-strand specific nuclease S₁ digestion and reactivity with anticytidine antibodies. Highly modified poly(dG-dC)·poly(dG-dC) was almost completely resistant to nuclease S₁ hydrolysis, while, modified DNA and poly(dG)·poly(dC) are highly susceptible to digestion. Two possible conformations for deoxyguanosine modified at the C-8 position by AAF are compared depending on whether its position is in alternating purine-pyrimidine sequences or random sequence DNA.     

DNA sequence analysis of mutations induced by N-2-acetylamino-7-iodofluorene in plasmid pBR322 in Escherichia coli

The spectrum of mutations induced by N-2-acetylamino-7-iodofluorene (AAIF) was analyzed in a forward mutation system based on mutagenesis directed to a small restriction fragment in the tetracycline resistance gene of plasmid pBR322. AAIF was found to induce frameshift mutations and base-pair substitutions at approximately equal frequencies. The frameshift mutations were mostly deletions of single base-pairs, but -2 frameshifts and +1 frameshifts were also detected. With one exception, the substitutions were transversions initiated at a G.C base-pair. Both frameshift mutations and transversions occurred preferentially at sites of repetitive guanine residues. Although AAIF and the related aromatic amines N-2-acetylaminofluorene (AAF) and N-2-aminofluorene (AF) all bind to the C-8 position of guanine, they have different effects on DNA conformation, and these differences are reflected in their mutation spectra. Previous studies have provided evidence that AAF adducts can trigger a B to Z conformational change in alternating GC sequences or displacement of the guanine by the fluorene ring in other sequences; the principal result is two classes of frameshift mutations. AF, whose DNA interaction involves outside binding rather than insertion and denaturation, primarily induces base-pair substitutions. AAIF adducts are chemically similar to AAF adducts, but the iodo group apparently hinders insertion of the fluorene ring into DNA. Consistent with this model, the mutation spectrum of AAIF combines properties of the mutation spectra of both AAF and AF.     

Mutagenesis by single site-specific arylamine-DNA adducts. Induction of mutations at multiple sites

Two related carcinogen adducts, N-(deoxyguanosin-8-yl)-2-aminofluorene (AF) or N-(deoxyguanosin-8-yl)-N-acetyl-2-aminofluorene (AAF), were introduced into the lacZ' gene at base position 6253 of the minus strand of M13mp9 viral DNA. The construction of this site-specifically modified DNA was accomplished by first preparing a gapped heteroduplex missing 7 nucleotides at position 6251-6257 followed by ligation with an unmodified heptamer or with a heptamer containing either an AF or AAF adduct. These site-specifically modified templates were transfected into competent wild-type Escherichia coli cells (JM103) and a uvrA strain (SMH12). The mutation spectrum was determined by phenotypic selection of colorless plaques indicating a defective beta-galactosidase marker enzyme and by an in situ hybridization procedure to detect single base pair mismatches in the adduct region. DNA sequencing was used to characterize 179 of the mutants obtained. We found that both adducts were capable of inducing base substitution mutations at the adduct site and in the local region of the adduct. A specific frameshift (+1G) was also observed at a displaced site. All of the frameshift mutations occurred at the ligation site of the modified oligonucleotide. Control experiments with an unmodified oligonucleotide did not show an enhancement of mutations at this site, indicating that the adducts may have been responsible for these frameshifts. The mutations spectra induced by these adducts suggest that mutagenesis depends not only on adduct structure but also the sequence in which the adduct is located and the host cell type used for mutation expression.     

Non-random binding of a chemical carcinogen to the DNA in chromatin

The distribution of a liver carcinogen (N-hydroxy-2-aminofluorene) along the DNA of chromatin has been studied using two nucleases as probes for the structure of chromatin. Rats were injected with the carcinogen and killed at various times after the injection. The nuclei of the liver were prepared and digested with Staphylococcal nuclease or pancreatic nuclease DNAse I. We show that the carcinogen is non randomly distributed along the DNA of chromatin since it binds preferentially to the regions of chromatin digested by the Staphylococcal nuclease whereas it is preferentially bound to the DNAse I resistant fraction. Our results also indicate that the two nucleases do not recognize exactly the same region of chromatin.     

Occurrence of protein kinases NI and NII in human and porcine thyroids

Cyclic nucleotide-independent protein kinases that preferentially phosphorylated casein and phosvitin as substrate were detected in the nuclei of human and porcine thyroid tissues, and compared with those from rat liver. Enzymes were extracted from the isolated nuclei with a buffer solution containing 0.4 M NaCl, and analyzed by DEAE-Sephadex and phosphocellulose column chromatographies. The chromatographies, together with the characterization of the enzymes, demonstrated that human and porcine thyroid tissues contained two major casein kinases in the cell nuclei, the properties of which revealed that they are to be identified as protein kinases NI and NII.     

Energy minimized structures of carcinogen-DNA adducts: 2-acetylaminofluorene and 2-aminofluorene

Energy minimized structures of DNA modified by the aromatic amines 2-acetylaminofluorene (AAF) and 2-aminofluorene (AF), for which no experimental atomic resolution data exist, are presented. These have been computed with a new molecular mechanics program specifically designed to define distortions imposed by such adducts, and employing a rational strategy for searching the conformation space of a DNA molecule with covalently linked carcinogen. In alternating G-C sequences, the AAF adduct prefers to reside at the exterior of an undeformed Z-helix. It can also induce base displacement with attendant denaturation and helix bending in sequences that disfavor the Z form, but undeformed B helices are excluded. The AF adduct, by contrast, prefers the major groove of an unperturbed B-helix, but can also induce carcinogen-base stacking in single stranded regions of the DNA, such as at the replication fork. The different biological properties of these two adducts may be related to their distinct     

Reduction of 2-acetylaminofluorene-induced unscheduled DNA synthesis in human and rat hepatocytes by butylated hydroxytoluene

Butylated hydroxytoluene (BHT) protected against DNA damage induced in rat hepatocytes by 2-acetylaminofluorene (2AAF) or N-hydroxy 2AAF as shown by a marked reduction of unscheduled DNA synthesis. BHT also inhibited 2AAF-induced DNA damage (as shown by reduced repair) in human hepatocytes. In addition, rats pre-treated with BHT in the diet (0.5% w/w for 10 days) provided hepatocytes which exhibited less unscheduled DNA synthesis than did hepatocytes from control rats when these cells were exposed to either 2AAF or N-hydroxy 2AAF. The results indicate both direct (in vitro) and indirect (by pre-treatment in vivo) inhibitory effects of BHT on the genotoxicity of 2AAF in liver cells, in accord with the reported anti-tumorigenicity in the liver. This effect contracts with a BHT-mediated increase in the efflux of 2AAF-derived mutagens from liver cells which may contribute to enhanced extrahepatic carcinogenesis.     

Carcinogen susceptibility is regulated by genome architecture and predicts cancer mutagenesis

The development of many sporadic cancers is directly initiated by carcinogen exposure. Carcinogens induce malignancies by creating DNA lesions (i.e., adducts) that can result in mutations if left unrepaired. Despite this knowledge, there has been remarkably little investigation into the regulation of susceptibility to acquire DNA lesions. In this study, we present the first quantitative human genome‐wide map of DNA lesions induced by ultraviolet (UV) radiation, the ubiquitous carcinogen in sunlight that causes skin cancer. Remarkably, the pattern of carcinogen susceptibility across the genome of primary cells significantly reflects mutation frequency in malignant melanoma. Surprisingly, DNase‐accessible euchromatin is protected from UV, while lamina‐associated heterochromatin at the nuclear periphery is vulnerable. Many cancer driver genes have an intrinsic increase in carcinogen susceptibility, including the BRAF oncogene that has the highest mutation frequency in melanoma. These findings provide a genome‐wide snapshot of DNA injuries at the earliest stage of carcinogenesis. Furthermore, they identify carcinogen susceptibility as an origin of genome instability that is regulated by nuclear architecture and mirrors mutagenesis in cancer.     

Nuclease sensitivity of active chromatin.

The active regions of chicken erythrocyte nuclei were labeled using the standard DNase I directed nick translation reaction. These nuclei were then used to study the characteristics and, in particular, the nuclease sensitivity of active genes. Although DNase I specifically attacks active genes, micrococcal nuclease solubilizes these regions to about the same degree as the total DNA. On the other hand micrococcal nuclease does selectively cut the internucleosomal regions of active genes resulting in the appearance of mononucleosomal fraction which is enriched in active gene DNA. A small percentage of the active chromatin is also released from the nucleus by low speed centrifugation following micrococcal nuclease treatment. The factors which make active genes sensitive to DNase I were shown to reside on individual nucleosomes from these regions. This was established by showing that isolated active mononucleosomes were preferentially sensitive to DNase I digestion. Although the high mobility group proteins are essential for the maintenance of DNase I sensitivity in active regions, these proteins are not necessary for the formation of the conformation which makes these genes preferentially accessible to micrococcal nuclease. The techniques employed in this paper enable one to study the chromatin structure of the entire population of actively expressed genes. Previous studies have elucidated the structure of a few special highly prevalent genes such as ovalbumin and hemoglobin. The results of this paper show that this special conformation is a general feature of all active genes irregardless of the extent of expression.     

Energy Minimized Structures of Carcinogen-DNA. Adducts: 2-Acetylaminofluorene and 2-Aminofluorene

Abstract

Energy minimized structures of DNA modified by the aromatic amines 2-acetylaminofluorene (AAF) and 2-aminofuorene (AF), for which no experimental atomic resolution data exist, are presented. These have been computed with a new molecular mechanics program specifically designed to define distortions imposed by such adducts, and employing a rational strategy for searching the conformation space of a DNA molecule with covalently linked carcinogen. In alternating G-C sequences, the AAF adduct prefers to reside at the exterior of an undeformed Z-helix. It can also induce base displacement with attendant denaturation and helix bending in sequences that disfavor the Z form, but undeformed B helices are excluded. The AF adduct, by contrast, prefers the major groove of an unperturbed B-helix, but can also induce carcinogen-base stacking in single stranded regions of the DNA, such as at the replication fork. The different biological properties of these two adducts may be related to their distinct conformational features.     

DNase I digestion as a tool for the quantitative evaluation of C-heterochromatic-DNA in situ.

The amount of DNA resisting the C-banding pre-treatments (C-heterochromatic-DNA) was found to account for the interspecific differences of genome size in different Primate groups. The evaluation of this parameter is therefore of great interest in cytotaxonomy. In this work, DNase I digestion was used instead of the pre-treatments C-banding, in an attempt to set up a suitable method for the quantitative evaluation of C-heterochromatic-DNA in both metaphase chromosomes and interphase chromatin. In fact DNase I is known to preferentially digest "active or potentially active" chromatin, and the highly repetitive and inactive DNA in C-heterochromatin should characteristically resist DNase I cleavage. As a model system, differently fixed mouse splenocytes were treated with DNase I for various times, and the digestion was monitored by flow cytometry after propidium iodide staining. In addition, mouse metaphase preparations from lymphocyte cultures were also digested with DNase I, and the amount of residual DNA was evaluated by static microfluorometry. Under controlled conditions of fixation, enzyme concentration, time and temperature, the same limit-digest can be obtained in both interphase nuclei and metaphases, which corresponds to the amount of residual DNA after C-banding and has a C-banding-like pattern in chromosomes.     

Mutagenesis by site-specific arylamine adducts in plasmid DNA: enhancing replication of the adducted strand alters mutation frequency

Site specifically modified plasmids were used to determine the mutagenic effects of single arylamine adducts in bacterial cells. A synthetic heptadecamer bearing a single N-(guanin-8-yl)-2-aminofluorene (AF) or N-(guanin-8-yl)-2-(acetylamino)fluorene (AAF) adduct was used to introduce the adducts into a specific site in plasmid DNA that contained a 17-base single-stranded region complementary to the modified oligonucleotide. Following transformation of bacterial cells with the adduct-bearing DNA, putative mutants were detected by colony hybridization techniques that allowed unbiased detection of all mutations at or near the site of the adduct. The site-specific AF or AAF adducts were also placed into plasmid DNA that contained uracil residues on the strand opposite that bearing the lesions. The presence of uracil in one strand of the DNA decreases the ability of the bacterial replication system to use the uracil-containing strand, thereby favoring the use of the strand bearing the adducts. In a comparison of the results obtained with site specifically modified DNA, either with or without uracil, the presence of the uracil increased the mutation frequencies of the AF adduct by greater than 7-fold to 2.9% and of the AAF adduct by greater than 12-fold to 0.75%. The mutation frequency of the AF adduct was greatly reduced in a uvrA- strain while no mutations occurred with the AAF adduct in this strain. The sequence changes resulting from these treatments were dependent on adduct structure and the presence or absence of uracil on the strand opposite the adducts.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro model for the nuclear transport of the hepadnavirus genome.

Hepadnaviruses contain a DNA genome, but they replicate via an RNA intermediate, synthesized by the cellular RNA polymerase II in the nucleus of the infected cell. Thus, nuclear transport of the viral DNA is required in the viral life cycle. Protein-free DNA is only poorly imported into the nucleus, so one or more of the viral proteins must be involved in the transport of the viral genome. In order to identify these viral proteins, we purified woodchuck hepadnavirus (WHV) core particles from infected woodchuck liver, isolated WHV DNA, and extracted the covalent complex of viral polymerase from the particles using urea. Intact core particles, the polymerase-DNA complex, or protein-free WHV DNA from core particles was added to digitonin-permeabilized HuH-7 cells, in which the cytosol was substituted by rabbit reticulocyte lysate (RRL) and an ATP-generating system. The distribution of the viral genome was analyzed by semiquantitative PCR or by hybridization in total nuclei, RRL, nuclear membranes, and nucleoplasm. The polymerase-DNA complex was efficiently transported into the nucleus, as indicated by the resistance of the nucleus-associated DNA to a short-term treatment with DNase I of the intact nuclei. The DNA within core particles stayed mainly in the cytosol and remained protected against DNase I. A minor part of the encapsidated DNA was bound to nuclei. It was protected against DNase I but became accessible after disruption of the nuclei. Deproteinized viral DNA completely remained in the cytosol. These data show that the viral polymerase is probably sufficient for mediating the transport of a hepadnavirus genome into the nucleus and that the viral core particles may release the genome at the nuclear membrane.     

Identity and activities of lysosomal enzymes in parenchymal and non-parenchymal cells from rat liver.

1. Intact parenchymal and non-parenchymal cells were isolated from rat liver. The parenchymal cells were purified by differential centrifugation, while non-parenchymal cells were obtained free of parenchymal cell contamination by preferentially destroying the parenchymal cells with the aid of pronase (0.25%). 2. The ability to isolate pure intact parenchymal and non-parenchymal cells permitted the characterization and measurement of specific activities of various lysosomal enzymes, representing the main functional hydrolytic activities of the lysosomes in these distinct cell types. 3. Lysosomal enzymes catalysing the hydrolysis of the terminal carbohydrate moiety of glycoproteins and glycolipids were not particularly enriched in the non-parenchymal cells as compared to parenchymal cells. The ratio of the specific activities of non-parenchymal cells over parenchymal cells varied between 0.7 for N-acetyl-beta-D-hexoseaminidase to 2.1 for alpha-glucosidase. This suggests no specific role of the non-parenchymal cells in the hydrolysis of terminal carbohydrate moieties of glycoproteins and glycolipids. 4. The enzymes acid phosphatase and aryl sulphatase, representing the phosphate and sulphate hydrolyzing activities, were enriched in the non-paranchymal cells as compared to the parenchymal cells by a factor of 2.5. 5. The most important peptidase cathepsin D, representing protein breakdown capacity, is enriched in the non-parenchymal cells as compared to parenchymal cells by a factor 6.0, suggesting a possible specific function of non-parenchymal cells in protein breakdown. 6. The most enriched lysosomal enzyme, representing lipid hydrolysis, is acid lipase, which is enriched in the non-parenchymal cells with a factor of 10. 7. The distribution of lysosomal enzymes between parenchymal and non-parenchymal cells suggests different functional roles of the lysosomes in these cell types. It can be concluded that the non-parenchymal cells possess a set of lysosomal enzymes which makes them extremely suitable for a phagocytic and antimicrobial function in the liver.     

Tumor hypersensitive DNA is enriched in c-myc sequences and reacts differentially with normal and malignant genomic DNA

We now show that exposure of B16 melanoma cells to bromodeoxyuridine increases cell-substratum interactions concurrent with an increase in genome susceptibility to nucleases. Hypersensitive DNA was isolated after mild nicking of nuclei with DNase I followed by repair with DNA polymerase I in the presence of biotin-19-SS-dUTP and affinity chromatography on streptavidin-agarose. Dot blot studies showed that the hypersensitive DNA is enriched in c-myc sequences compared to total tumor genomic DNA, and hybridizes preferentially to the latter, compared to normal genomic DNA, particularly when prepared from BrdU-treated cells. Since hypersensitive DNA can hybridize with multiple Alu sequences in the genome, we postulate that one of the mechanisms for its differential reactivity may be by recognition of an unequal number of Alu repeats in normal and tumor genomic DNA.