Recombinational repair of hydrogen peroxide-induced damages in DNA of phage T4

Viral Aggregation: Impact on Virus Behavior in the Environment

Aggregates of viruses can have a significant impact on quantification and behavior of viruses in the environment. Viral aggregates may be formed in numerous ways. Viruses may form crystal like structures and aggregates in the host cell during replication or may form due to changes in environmental conditions after virus particles are released from the host cells. Aggregates tend to form near the isoelectric point of the virus, under the influence of certain salts and salt concentrations in solution, cationic polymers, and suspended organic matter. The given conditions under which aggregates form in the environment are highly dependent on the type of virus, type of salts in solution (cation, anion. monovalent, divalent) and pH. However, virus type greatly influences the conditions when aggregation/disaggregation will occur, making predictions difficult under any given set of water quality conditions. Most studies have shown that viral aggregates increase the survival of viruses in the environment and resistance to disinfectants, especially with more reactive disinfectants. The presence of viral aggregates may also result in overestimation of removal by filtration processes. Virus aggregation-disaggregation is a complex process and predicting the behavior of any individual virus is difficult under a given set of environmental circumstances without actual experimental data.

Bile compound-induced DNA damage and repair in bacteriophage T4

Two bile acids (cholic acid and chenodeoxycholic acid) and two bile salts (sodium cholate and sodium deoxycholate) were shown to inactivate bacteriophage T4. The inactivation was largely reversed when the phage was allowed to undergo recombinational repair, indicating that bile compounds cause DNA damage.

Radioprotection of beta-carotene evaluated on mouse somatic and germ cells

In the present paper, the protective effect of beta-carotene was evaluated after whole body exposure of mice to 2 Gy of X-rays. Splenocytes, reticulocytes, bone marrow cells and spermatids were evaluated for the frequency of micronuclei (MN) induced by X-rays. Mice were treated (gavage) with beta-carotene (10, 25 and 50 mg/kg b.w.) for 5 consecutive days and, 4 h after the last treatment, the animals were irradiated. The results obtained showed different frequencies of X-ray-induced-MN between different cell populations analysed and also different response of these cells to the beta-carotene treatment. The radioprotective effect of beta-carotene was observed in splenocytes, reticulocytes, and spermatids but not in bone marrow cells. No dose-response relationship for beta-carotene was detected. The time of sampling, the sensitivity of the cells as well as the antioxidant activity of beta-carotene are discussed as important factors for the radioprotective action of this provitamin.

Biological properties of peroxide-containing tooth whiteners

Peroxides have been used in tooth whitening for more than 100 years. Current peroxide-containing whiteners can be classified into three categories: (1) those containing high concentrations of peroxides for professional use only; (2) materials dispensed by dentists and used by patients at home; and (3) over-the-counter products available directly to consumers for home use. Hydrogen peroxide (H2O2) and carbamide peroxide are the most commonly used active ingredients in these whiteners. Both peroxides have long been used safely in oral health products and are accepted by the US Food and Drug Administration. However, questions have been raised regarding the safety of at-home whiteners because the peroxides appear to constitute a new use. Substantial differences exist in the manner of application between at-home whiteners and oral health products. In addition, tooth whiteners are a mixture of various ingredients; possible interactions may occur because of the active nature of peroxides. Therefore, the safety evidence for peroxide-containing whiteners is considered inadequate. This paper will review the history of using peroxides for tooth whitening, the toxicology of H2O2 and carbamide peroxide, and available information on the safety of whiteners. The rationale and approaches for evaluating biological properties of peroxide containing whiteners are also discussed.

Radioprotective effect of vitamins C and E

Albino rats were treated with aqueous vitamin C solution and vitamin E solution dissolved in olive oil at two concentrations, 100 and 300 mg/kg/day, for 6 months. Some of the animals were then subjected to whole-body irradiation. Chromosomal aberrations and mitotic activity in non-irradiated and irradiated groups were recorded. Both vitamins were found to be non-mutagenic. Vitamin C exerted a radioprotective effect but vitamin E was not radioprotective and it suppressed the radioprotection otherwise produced by olive oil.

Studies on mammalian mutants defective in rejoining double-strand breaks in DNA

Mutants with defects in the rejoining of DNA double-strand breaks (dsbs) have been identified and characterised from E. coli and the yeast, Saccharomyces cerevisiae. More recently, 3 mammalian cell mutants with defective dsb rejoining have also been described. These mutants are xrs, XR-1 and L5178Y/S, and they are derived from at least two distinct complementation groups. The aim of this article is to review the current status of the studies with these mammalian cell mutants which are defective in dsb rejoining and, in particular, to compare their properties with those mutants identified from lower organisms. Possible mechanistic differences in the process of dsb rejoining between prokaryotes and lower and higher eukaryotes are discussed. All the mammalian mutants defective in dsb rejoining, are sensitive primarily to ionising radiation with little cross-sensitivity to UV-radiation. This is similar to the rad52 mutants of S. cerevisiae but contrasts to the majority of the E. coli mutants with defective dsb rejoining. Where studied, the mammalian cell mutants show enhanced resistance to ionizing radiation in late S/G2 phase, which, in one case, correlates with an enhanced ability to rejoin dsbs. This, together with other evidence, suggests that two mechanisms of dsb rejoining may exist in higher eukaryotes, one which operates uniquely in S/G2 phase and a second mechanism operating throughout the cell cycle and dependent upon the xrs and XR-1 gene products (although whether the xrs and XR-1 dependent pathways are distinct cannot at present be ascertained). Since duplicate homologues will be present in late S/G2 phase cells, this pathway may involve a recombinational mechanism. The xrs-dependent pathway might involve illegitimate recombination, but the xrs mutants do not appear to have a major defect in homologous recombination (involving plasmid DNA) and in this respect are distinct from rad52 mutants.

Yeast gene RAD52 can substitute for phage T4 gene 46 or 47 in carrying out recombination and DNA repair

The RAD52 gene of Saccharomyces cerevisiae and genes 46 and 47 of bacteriophage T4 are essential for most recombination and recombinational repair in their respective organisms. The RAD52 gene was introduced into expression vectors that were used to transform Escherichia coli. The expression of RAD52 was then induced, and the ability of RAD52 to complement phage mutants defective in gene 46 or 47 was determined with respect to the three criteria of phage growth, recombination, and recombinational repair. RAD52 gene expression was found to allow growth of gene 46 and 47 mutants under otherwise restrictive conditions, as measured by plaque formation and burst size. Expression of the RAD52 gene also restored the ability of gene 46 and 47 mutants to undergo recombination of rII markers. Furthermore, the RAD52 gene restored the ability of gene 46 and 47 mutants to undergo recombinational repair after UV irradiation. The published DNA sequence of gene RAD52 was compared with the published sequences of genes 46 and 47. Although overall sequence similarities were only marginally significant, RAD52 and gene 46 had substantial sequence similarity over a limited region.