ADP-ribosylation of proteins in nuclei and mitochondria from tissues rats of various age exposed gamma-radiation

Constitutive and gamma-induced ADP-ribosylation of nuclei and mitochondrial proteins in 2- and 29-month-old rats was studied. ADP-ribosylation was determined by binding of [3H]-adenin with the proteins after incubation of cellular organells in reaction mixture supplemented with [adenin-2,8-3H]-NAD. It was detected that the level of total protein ADP-ribosylation in the nuclei is 4.5-6.2 times higher than in the mitochondria. By inhibition of poly(ADP-ribose) polymerase (PARP) with 3-aminobenzamidine and treatment of ADP-ribosylated proteins with phosphodiesterase I, it was demonstrated that about 90% of [3H]-adenin bound by proteins in the nuclei and 70% in the mitochondria was the result of PARP activity. The level of total ADP-ribosylation of nuclear and mitochondrial proteins in the tissues of old rats was reliably lower than in young animals. This reduction of ADP-ribosylation in old animals is the result of the lower activity of PARP, not of mono(ADP-ribosyl) transferase (MART). The level of ADP-ribosylation of proteins in the nuclei of brain and spleen cells of 2-month-old rats irradiated with of 5 and 10 Gy was by 49-109% higher than in the control. At the same doses of radiation, the level of ADP-ribosylation of nuclear proteins in brain and spleen of old rats increased only by 29-65% compared to the control. Unlike cell nuclei, the radiation-induced activation of ADP-ribosylation in mitochondria was less expressed: the level of ADP-ribosylation increased by 34-37% in young rats and by 11-27% in old animals. This increased binding of ADP-ribose residues by the proteins of nuclei and mitochondria from tissues of gamma-irradiated rats is exceptionally conditioned by activation of poly(ADP-ribosyl)ation because the level of mono(ADP-ribosyl)ation remains constant. The results of this study enable the suggestion that poly(ADP-ribosyl)ation also occurs in the mitochondria of brain and spleen cells of the gamma-irradiated rats, though less pronounced than in cell the cell nuclei of these tissues. Thus, one of the probable causes of the less efficient repair of radiation-induced DNA damage in old organisms is a decline of both constitutive and induced poly(ADP-ribosyl)ation of proteins in cell nucleus and mitochondria.     

DNA-protein cross-links in nuclei and mitochondria of tissue cells from rats of various age exposed to gamma-radiation

The formation and repair of DNA-protein cross-links (DPC) in the mitochondria and nuclei from the brain and spleen of 2- and 29-month rats after their exposure to ionizing radiation were studied. The background level of DPC in brain and spleen mitochondria of old rats was shown to be about two times as high as in young rats. In the nuclei from the brain of old rats the background amount of DPC was also increased, unlike the nuclei of spleen of the same rats. At the doses 5 and 10 Gy (137Cs), the amount of DPC produced in the mitochondria and nuclei of brain and spleen of 29-month rats was 1.8-2.5 times greater than in the nuclei of the same tissues of young animals. At the same time, in the mitochondria of brain and spleen from irradiated rats the amount of DPC was by 30-80% higher than in the nuclei of the same tissues. Analysis of changes in DPC content during the post-radiation period showed that 5 h after irradiation of rats with a dose of 10 Gy, the level of these lesions in the nuclei of brain and spleen of young rats decreased by 40 and 65%, respectively, whereas the amount of these lesions in the mitochondria did not decrease. In this post-radiation period in nuclei of brain and spleen of old rats the amount of DPC decreased by 20-40%, respectively. However, the data on DPC obtained for the mitochondria of brain and spleen from both young and old rats showed that the amount of these lesions did not decrease during the 5 h post-radiation period. These results enable the suggestion that mitochondria do not possess a system of DPC repair. To summarize, ionizing radiation initiates in the nuclei of brain and spleen of old rats more DPC and their repair proceeds slower than in the nuclei of the same tissues of young animals. In the mitochondria of gamma-radiation exposed old rats more DPC are also produced than in young rats but no repair of DPC is observed in both old and young animals within the 5 h post-radiation period.     

Strand specificity for UV-induced DNA repair and mutations in the Chinese hamster HPRT gene.

DNA excision repair modulates the mutagenic effect of many genotoxic agents. The recently observed strand specificity for removal of UV-induced cyclobutane dimers from actively transcribed genes in mammalian cells could influence the nature and distribution of mutations in a particular gene. To investigate this, we have analyzed UV-induced DNA repair and mutagenesis in the same gene, i.e. the hypoxanthine phosphoribosyl-transferase (hprt) gene. In 23 hprt mutants from V79 Chinese hamster cells induced by 2 J/m2 UV we found a strong strand bias for mutation induction: assuming that pre-mutagenic lesions occur at dipyrimidine sequences, 85% of the mutations could be attributed to lesions in the nontranscribed strand. Analysis of DNA repair in the hprt gene revealed that more than 90% of the cyclobutane dimers were removed from the transcribed strand within 8 hours after irradiation with 10 J/m2 UV, whereas virtually no dimer removal could be detected from the nontranscribed strand even up to 24 hr after UV. These data present the first proof that strand specific repair of DNA lesions in an expressed mammalian gene is associated with a strand specificity for mutation induction.     

Deficient repair of the transcribed strand of active genes in Cockayne's syndrome cells.

Removal of ultraviolet light induced cyclobutane pyrimidine dimers (CPD) from active and inactive genes was analyzed in cells derived from patients suffering from the hereditary disease Cockayne's syndrome (CS) using strand specific probes. The results indicate that the defect in CS cells affects two levels of repair of lesions in active genes. Firstly, CS cells are deficient in selective repair of the transcribed strand of active genes. In these cells the rate and efficiency of repair of CPD are equal for the transcribed and the nontranscribed strand of the active ADA and DHFR genes. In normal cells on the other hand, the transcribed strand of these genes is repaired faster than the nontranscribed strand. However, the nontranscribed strand is still repaired more efficiently than the inactive 754 gene and the gene coding for coagulation factor IX. Secondly, the repair level of active genes in CS cells exceeds that of inactive loci but is slower than the nontranscribed strand of active genes in normal cells. Our results support the model that CS cells lack a factor which is involved in targeting repair enzymes specifically towards DNA damage located in (potentially) active DNA.     

Increase of mitochondrial DNA copies with low level of DNA repair in tissue cells of gamma-irradiated mice

The damage and the change in the number of mitochondrial DNA (mtDNA) copies in brain and spleen tissues of gamma-irradiated mice were studied. The changes in the number of mitochondrial DNA (mtDNA) copies were assayed by the comparative analysis of the density values of long-extension PCR products of the mtDNA fragments (16 kb) and the cluster nuclear gene of beta-globin (8.7 kb). PCRs of mtDNA fragments and the nuclear gene of beta-globin were carried out simultaneously in one test-tube within total DNA. Our results showed that in brain and in spleen cells of mice exposed to gamma-radiation an increase in copy number (polyploidization) of mtDNA with regard to the nuclear gene beta-globin took place. The induction of polyploidization of mtDNA observed in cells of gamma-irradiated animals is regarded as the development of a compensatory reaction because of the energy deficiency due to the increased ATP consumption and structural alteration of genes controlling OXPHOS. The data enabled the assumption that because of the low efficiency of repair systems in mitochondria the induction of synthesis of new mtDNA copies on intact or little affected mtDNA templates may be the major mechanism for the retention of the mitochondrial genome which is constantly damaged by the endogenous ROS and is affected by ionizing radiation and/or other exogenous factors.     

Molecular breeding of polymerases for amplification of ancient DNA

In the absence of repair, lesions accumulate in DNA. Thus, DNA persisting in specimens of paleontological, archaeological or forensic interest is inevitably damaged. We describe a strategy for the recovery of genetic information from damaged DNA. By molecular breeding of polymerase genes from the genus Thermus (Taq (Thermus aquaticus), Tth (Thermus thermophilus) and Tfl (Thermus flavus)) and compartmentalized self-replication selection, we have evolved polymerases that can extend single, double and even quadruple mismatches, process non-canonical primer-template duplexes and bypass lesions found in ancient DNA, such as hydantoins and abasic sites. Applied to the PCR amplification of 47,000-60,000-year-old cave bear DNA, these outperformed Taq DNA polymerase by up to 150% and yielded amplification products at sample dilutions at which Taq did not. Our results demonstrate that engineered polymerases can expand the recovery of genetic information from Pleistocene specimens and may benefit genetic analysis in paleontology, archeology and forensic medicine.     

Patterns in the degradation of individual genes of thymocytes in irradiated rats

Degradation of genes of actin, albumin, histones, heat shock protein, and ribosomal RNA within DNA of irradiated animal thymocytes has been investigated. It has been shown that single strand enzymatic breaks occurred in thymocyte DNA 2 h following irradiation are localized in linker sites of nucleosomes. All the transcribed genes under study degrade to fragments that correspond by their length to DNA of nucleosomes and their oligomers. The albumin gene nontranscribed in thymocytes also degrades; however, no low molecular weight fragments are found. The degree of gene degradation is invariable in time.     

Sites of preferential induction of cyclobutane pyrimidine dimers in the nontranscribed strand of lacI correspond with sites of UV-induced mutation in Escherichia coli

An approach utilizing fluorescence-activated DNA sequencing technology was used to study the position and frequency of UV-induced lesions in the lacI gene of Escherichia coli. The spectrum of sites of UV damage in the NC+ region of the gene was compared with a published spectrum of UV-induced mutation in lacI (Schaaper, R.M., Dunn, R.L., and Glickman, B.W. (1987) J. Mol. Biol. 198, 187-202). On average, the frequency of UV-induced lesions in the nontranscribed strand was higher than that in the transcribed strand in the region analyzed. A large fraction of mutations occurs at sites of UV-induced lesions in the nontranscribed strand, but not in the transcribed strand. This bias is reduced in an excision repair deficient (UvrB-) strain. In addition, mutations occur overwhelmingly at sites where a dipyrimidine sequence is present in the nontranscribed strand. This bias is also markedly reduced in the UvrB- strain. In light of recent work Mellon and Hanawalt (Mellon, I., and Hanawalt, P.C. (1989) Nature 342, 95-98) describing the preferential removal of cyclobutane dimers from the transcribed strand of the expressed lacZ gene in E. coli, our data suggest that preferential strand repair may have a significant effect on mutagenesis.     

Gene-specific oxidative lesions in aged rat brain detected by polymerase chain reaction inhibition assay

An exposure of isolated rat brain genomic DNA to oxidative stress in the form of iron salts (Fe²⁺) and ascorbate results in gene-specific DNA lesions detectable by a quantitative polymerase chain reaction (PCR) based assay in which PCR amplification efficiency of the affected genes (e.g. β-actin and p53) is grossly impaired. Such oxidative DNA lesions are prevented by hydroxyl radical scavengers like mannitol (20 mM) and sodium benzoate (20 mM) or by the antioxidant enzyme catalase (50 μg/ml) present in the incubation mixture during exposure to Fe²⁺ and ascorbate. When brain DNA isolated from young (4–6 months of age) and aged (20–24 months of age) rats are analyzed similarly by the PCR based method, the amplification levels of β-actin and p53 genes are noticeably decreased in the case of aged rat indicating an accumulation of gene-specific DNA lesions during brain aging.