Analysis of macromolecule alkylation in tissues of intact and tumor carrying mice]

Alkylation DNA reparation kinetics and the disintegration of alkylated RNA, proteins and lipids in liver, spleen and brain of intact and 22A hepatomic mice after a injection of 1-14C-nitrosomethylurea at a therapeutic dose are studied. The tissue studied are different in their macromolecules and lipids alkylation, in DNA reparation and RNA, protein and lipid degradation rates. Possible correlation between the time of the occurrence of DNA damages and the frequency of tumour emergence in different tissues is discussed. It is found that normal cells eliminate more rapidly degraded RNA, protein and lipid molecules and more rapidly repair DNA damages as compared with 22A hepatoma cells. It is suggested to be due to more rapid macromolecule metabolism in normal cells which specifies a selective sensitivity of tumour cells to alkylating agents and nitrosoalkylureas. The time of the occurrence of damages induced with alkylating agents and nitrosomethylureas is supposed to be a critical parameter in processes resulting in the selective sensitivity of normal and tumour cells.     

Qantitative description of mammalian cell recovery after combined exposure to ionizing radiation with chemical agents

The parameters of recovery of mammalian cells after exposure to ionizing radiation combined with chemical agents were calculated based on a mathematical model of post-radiation recovery. The data presented, in contrast to the previously published results, indicate that the inhibition of the recovery may be due either to the damage or disruption of the process of recovery or the increase in the part of irreversible damages from which the cells are incapable to recover; or both of these processes can be realized simultaneously. It is concluded that the combination of ionizing radiation with chemical agents that inhibit the recovery processes through the formation of irreversible damages or affect the probability of recovery can be a perspective way in terms of finding the most effective means to increase radiosensitivity.     

Saccharomyces cerevisiae-based system for studying clustered DNA damages

DNA-damaging agents can induce clustered lesions or multiply damaged sites (MDSs) on the same or opposing DNA strands. In the latter, attempts to repair MDS can generate closely opposed single-strand break intermediates that may convert non-lethal or mutagenic base damage into double-strand breaks (DSBs). We constructed a diploid S. cerevisiae yeast strain with a chromosomal context targeted by integrative DNA fragments carrying different damages to determine whether closely opposed base damages are converted to DSBs following the outcomes of the homologous recombination repair pathway. As a model of MDS, we studied clustered uracil DNA damages with a known location and a defined distance separating the lesions. The system we describe might well be extended to assessing the repair of MDSs with different compositions, and to most of the complex DNA lesions induced by physical and chemical agents.     

Characterization of DNA damages by filtration through nitrocellulose filters: a simple probe for DNA-modifying agents.

A simple technique for the detection of DNA-modifying agents is described. The double-stranded covalently closed circular DNA of phage PM2 is exposed to the modifying agent and then analysed for DNA damages by assays involving only incubation steps and filtration through nitrocellulose filters. The technique described allows the measurement of DNA modifications which lead to local denaturation of the DNA double helix, interstrand cross-links, single- and double-strand breaks, damages which render the phosphodiester bonds of the DNA sensitive to hydrolysis and damages which labilise the glycosylic bond between base and sugar moiety.     

Characterization of DNA damages by filtration through nitrocellulose filters: A simple probe for DNA-modifying agents

A simple technique for the detection of DNA-modifying agents is described. The double-stranded covalently closed circular DNA of phage PM2 is exposed to the modifying agent and then analysed for DNA damages by assays involving only incubation steps and filtration through nitrocellulose filters. The technique described allows the measurement of DNA modifications which lead to local denaturation of the DNA double helix, interstrand cross-links, single- and double-strand breaks, damages which render the phosphodiester bonds of the DNA sensitive to hydrolysis and damages which labilise the glycosylic bond between base and sugar moiety.     

Base excision repair in yeast and mammals

Base excision repair (BER), as initiated by at least seven different DNA glycosylases or by enzymes that cleave DNA at abasic sites, executes the repair of a wide variety of DNA damages. Many of these damages arise spontaneously because DNA interacts with the cellular milieu, and so BER profoundly influences spontaneous mutation rates. In addition, BER provides significant protection against the toxic and mutagenic effects of DNA damaging agents present in the external environment, and as such is likely to prevent the adverse health effects of such agents. BER pathways have been studied in a wide variety of organisms (including yeasts) and here we review how these varied studies have shaped our current view of human BER.     

Effects of base damages on DNA replication.

Understanding the response of DNA polymerase to the encountered damage in a template is a key to assessing lethal and mutagenic events of cells exposed to genotoxic agents. In the present study M13 (or f1) DNA templates containing 4 types of thymine damages were prepared, and DNA synthesis was carried out in vitro with the templates. The extent of inhibition of DNA synthesis by the damages was evaluated by measuring [3H]dTMP incorporation. Furthermore, newly synthesized DNA was analyzed on a sequencing gel to determine termination sites of DNA synthesis. The results showed that DNA synthesis was differentially inhibited by the damages, and the termination sites of DNA synthesis were dependent on the structures of the damages and the 3'-5' exonuclease activity of DNA polymerase used.     

Synthesis and biological evaluation of bengacarboline derivatives

Novel derivatives of the marine alkaloid bengacarboline have been synthesized. The seco derivatives 11 and 12 were evaluated for topoisomerase inhibition, DNA damages, cytotoxicity and cell cycle perturbation. The two synthetic analogs are more potent cytotoxic agents than bengacarboline and they both induce an accumulation of cells in the S phase of DNA synthesis. They do not function as topoisomerase inhibitors but trigger DNA damages in cells.     

Mathematical model of a simultaneous combined effect of ionizing radiation and hyperthermia

A mathematical model has been proposed suggesting that the synergistic action of a combination of ionizing radiation and hyperthermia is conditioned by additional lethal damages arising from the interaction of "sub-lesions" induced by both agents. The model describes quantitatively the synergism of the combined action of the agents used and predicts the maximal value of the synergistic effect and conditions in which it can be achieved.     

Chemical and biochemical postlabeling methods for singling out specific oxidative DNA lesions.

A survey of the main available chemical and biochemical postlabeling assays for measuring oxidative DNA damage is reported. Two main approaches, radio and fluorescent postlabeling, have been used in order to reach a high level of sensitivity of detection. This is required for the measurement of DNA damage within cells and tissues upon exposure to agents of oxidative stress. Most of the methods are based on liquid chromatographic separation of defined DNA modifications following either acidic hydrolysis or enzymic digestion of DNA. In a subsequent step, the isolated base or sugar damages are either radiolabeled or made fluorescent by chemical or enzymatic reactions. Emphasis is placed on the recently developed high performance liquid chromatographic 32P-postlabeling assay, which allows the specific and sensitive measurement of various base damages including adenine N-1 oxide and 5-hydroxymethyluracil at the level of one modification per 10(7) normal bases in a sample size of 1 microgram of DNA. Examples of application of radioactive postlabeling to the measurement of DNA base damage following exposure of human cells to oxidizing agents including hydrogen peroxide and UVA radiation are provided.     

A new mechanism for repairing oxidative damage to DNA: (A)BC excinuclease removes AP sites and thymine glycols from DNA

Escherichia coli (A)BC excinuclease is the major enzyme responsible for removing bulky adducts, such as pyrimidine dimers and 6-4 photoproducts, from DNA. Mutants deficient in this enzyme are extremely sensitive to UV and UV-mimetic agents, but not to oxidizing agents, or ionizing radiation which damages DNA in part by generating active oxygen species. DNA glycosylases and AP1 endonucleases play major roles in repairing oxidative DNA damage, and thus it has been assumed that nucleotide excision repair has no role in cellular defense against damage by ionizing radiation and oxidative damage. In this study we show that the E. coli nucleotide excision repair enzyme (A)BC excinuclease removes from DNA the two major products of oxidative damage, thymine glycol and the baseless sugar (AP site). We conclude that nucleotide excision repair is an important cellular defense mechanism against oxidizing agents.     

Cellular role of yeast Apn1 apurinic endonuclease/3''-diesterase: repair of oxidative and alkylation DNA damage and control of spontaneous mutation.

The APN1 gene of Saccharomyces cerevisiae encodes the major apurinic/apyrimidinic endonuclease and 3'-repair DNA diesterase in yeast cell extracts. The Apn1 protein is a homolog of Escherichia coli endonuclease IV, which functions in the repair of some oxidative and alkylation damages in that organism. We show here that yeast strains lacking Apn1 (generated by targeted gene disruption or deletion-replacement) are hypersensitive to both oxidative (hydrogen peroxide and t-butylhydroperoxide) and alkylating (methyl- and ethylmethane sulfonate) agents that damage DNA. These cellular hypersensitivities are correlated with the accumulation of unrepaired damages in the chromosomal DNA of apn1 mutant yeast cells. Hydrogen peroxide-treated APN1+ but not apn1 mutant cells regenerate high-molecular-weight DNA efficiently after the treatment. The DNA strand breaks that accumulate in the Apn1-deficient mutant contain lesions that block the action of DNA polymerase but can be removed in vitro by purified Apn1. An analogous result with DNA from methylmethane sulfonate-treated cells corresponded to the accumulation of unrepaired DNA apurinic sites in the apn1 mutant cells. The rate of spontaneous mutation in apn1 mutant S. cerevisiae was 6- to 12-fold higher than that measured for wild-type yeast cells. This increase indicates that under normal growth conditions, the production of DNA damages that are targets for Apn1 is substantial and that such lesions can be mutagenic when left unrepaired.     

Complement Activation Products C3a and C4a as Endogenous Antimicrobial Peptides

All vertebrate species are constantly challenged by infectious agents and pathogens. In order to fight these infectious agents the human host has developed a sophisticated and powerful immune defense. The complement system, which represents the first defense line of innate immunity is activated immediately, within seconds. The activated immune system recognizes and damages an invading microbe, coordinates the host immune response and further orchestrates the adaptive immune response. Activation of the complement system leads to a rapid and amplified response which includes the generation of small peptides like C3a and C4a that display antimicrobial, anti-fungal and anaphylactic activity. Here we report how these antimicrobial peptides are generated during the immune response and summarize the functional mechanisms of these intrinsically generated anti microbial peptides.     

Sequence-targeted chemical modifications of nucleic acids by complementary oligonucleotides covalently linked to porphyrins.

Oligo-heptathymidylates covalently linked to porphyrins bind to complementary sequences and can induce local damages on the target molecule. In dark reactions, iron porphyrin derivatives exhibited various chemical reactivities resulting in base oxidation, crosslinking and chain scission reactions. Reactions induced by reductants, such as ascorbic acid, dithiothreitol or mercapto-propionic acid, led to very localised reactions. A single base was the target for more than 50% of the damages. Oxidising agents such as H2O2 and its alkyl derivatives induced reactions that extended to a wider range of altered bases. The specificity of the chemical modifications observed in these systems is discussed from a mechanistic point of view.     

Role of a change in oxygen concentration in modifying in vitro reproductive cell death. 3. Modification of radiosensitivity by compounds reducing oxygen

The data are discussed concerning the protection of cells in vitro by the oxygen reducing agents. The analysis has demonstrated that the protective effect of sulfites can only be related to hypoxia they create. Hypoxia also contributes considerably to the protective effect of thiols (maximum DMF approximately 3). However the protective effect of thiols cannot wholly be attributed to hypoxia. The oxygen--independent component of the protective effect of thiols (maximum DMF approximately 1.5) is conditioned by the metabolic changes increasing the enzymic repair of potential damages.     

药理性预适应的脑保护作用

基于对脑组织内源性保护作用缺血预适应的认识,近年来发现一些药物预处理可以诱导脑组织产生保护作用,称为药理性预适应。这些药物包括内毒素及其衍生物、3-硝基丙酸、吸入性麻醉剂、腺苷及其拟似物、ATP敏感钾通道的开放剂、吗啡类药物、去铁敏等。不同的药物诱导药理性预适应脑保护的时程和强度以及在具体机制方面存在一定差异。开发诱导脑药理性预适应的新药有望应用于神经外科及预防性脑保护。     

Mathematical modeling of synergistic interaction of sequential thermoradiation action on mammalian cells

Data obtained by other authors for mammalian cells treated by sequential action of ionizing radiation and hyperthermia were used to estimate the dependence of synergistic enhancement ratio on the ratio of damages induced by these agents. Experimental results were described and interpreted by means of the mathematical model of synergism in accordance with which the synergism is expected to result from the additional lethal damage arising from the interaction of sublesions induced by both agents.     

Biological role of histidine-containing dipeptides

The biological role of histidine-containing dipeptides is reviewed. The role of carnosine and anserine in muscle function is discussed from the evolutionary viewpoint. Evidence on the antioxidative effect of carnosine and its protection of biological membranes against lipid peroxidation-induced damages is presented. The effects of presently known natural antioxidative agents and carnosine on lipid peroxidation are compared. Carnosine has been shown to be a more universal protector of membranes as compared to free radical scavengers.