A single low dose of Fe ions can cause long-term biological responses in NL20 human bronchial epithelial cells.

Space radiation cancer risk may be a potential obstacle for long-duration spaceflight. Among all types of cancer space radiation may induce, lung cancer has been estimated to be the largest potential risk. Although previous animal study has shown that Fe ions, the most important contributor to the total dose equivalent of space radiation, induced a higher incidence of lung tumorigenesis per dose than X-rays, the underlying mechanisms at cellular level remained unclear. Therefore, in the present study, we investigated long-term biological changes in NL20 human bronchial epithelial cells after exposure to Fe ion or X-ray irradiation. We found that compared with sham control, the progeny of NL20 cells irradiated with 0.1 Gy of Fe ions showed slightly increased micronucleus formation, significantly decreased cell proliferation, disturbed cell cycle distribution, and obviously elevated intracellular ROS levels accompanied by reduced SOD1 and SOD2 expression, but the progeny of NL20 cells irradiated with 0.9 Gy of X-rays did not show any significant changes. More importantly, Fe ion exposure caused much greater soft-agar colony formation than X-rays did in the progeny of irradiated NL20 cells, clearly suggesting higher cell transformation potential of Fe ions compared with X-rays. These data may shed the light on the potential lung tumorigenesis risk from Fe ion exposure. In addition, ATM inhibition by Ku55933 reversed some of the changes in the progeny of Fe ion-irradiated cells but not others such as soft-agar colony formation, suggesting complex processes from DNA damage to carcinogenesis. These data indicate that even a single low dose of Fe ions can induce long-term biological responses such as cell transformation, etc., suggesting unignorable health risk from space radiation to astronauts.

Nanostructured oleic acid/polysorbate 80 emulsions with diminished toxicity in NL-20 cell line: Insights of potential drug carriers.

Nanoemulsions (NE) are nowadays required drug nanocarriers. We have selected i) oleic acid (OA) as oil (O), ii) polysorbate 80 (PS80) as surfactant (S), and iii) water (W) in a prototype NE. Our best formulation had O:S ratio [OA]/[PS80] = 0.0708/0.0382 = 1.85 [mol·L-1], implying 1.85 parts of OA covered/stabilized by 1 part of PS80, giving 71.86 nm and 0.42 polydispersity index (PDI) in NE, determined by DLS and TEM. These nanosystems stored at room temperature/darkness stabilized up to 12 months (measured by DLS and TEM) maintaining very similar particle sizes and sometimes decreasing PDI. NE stability was determined by DSC, evidencing reversibility upon heating from 25 to 100 °C, increasing to 125 °C (sealed systems) produced more attenuated heating profiles in second and third cycles, compared with first, indicating partial but enough stability for storage means. NE cytotoxicity tests were conducted on immortalized normal lung epithelial cells (NL-20), as reference. The results show 50 % inhibitory concentrations (IC50,µM) of 1100, OA, and 2.6, PS80. The IC50 was 20.5, PS80 (PS80@NE) and 37.9, OA (OA@NE) clearly indicating that components changed their toxicities upon nanostructuring, OA exhibited 30-fold increase (IC50(OA) 1100.0→37.9) while PS80, decreased 7.9-fold (IC50(PS80) 2.6→20.5). PS80 is the most toxic component but when is included in PS80@NE, less toxic nanocarriers were generated.

The role of plant metabolism in the mutagenic and cytotoxic effects of four organophosphorus insecticides in Salmonella typhimurium and in human cell lines.

This study used a cell/microbe co-incubation assay to evaluate the effect of four organophosphorus insecticides (parathion-methyl, azinphos-methyl, omethoate, and methamidophos) metabolized by coriander (Coriandrum sativum). The reverse mutation of Salmonella typhimurium strains TA98 and TA100 was used as an indicator of genetic damage. Treatments with these insecticides inhibited peroxidase activity in plant cells by between 17% (omethoate) and 98% (azinphos-methyl) and decreased plant protein content by between 36% (omethoate) and 99.6% (azinphos-methyl). Azinphos-methyl was the most toxic when applied directly. In the Ames test, treatments applied directly to strain TA100 killed the bacteria; however, the presence of plant metabolism detoxified the system and permitted the growth of bacteria. In strain TA98, plant metabolites of insecticides were mutagenic. This result suggests that the tested pesticides produce mutations through frameshifting. The same pesticides were applied to human skin (HaCaT) and lung (NL-20) cell lines to evaluate their effects on cell viability. Pesticides applied directly were more cytotoxic than the combination of pesticide plus coriander metabolic fraction. Omethoate and methamidophos did not affect the viability of HaCaT cells, but azinphos-methyl and parathion-methyl at 100 and 1000µgmL(-1) significantly decreased viability (p<0.05). The NL-20 cell line was remarkably sensitive to the direct application of insecticides. All of the treatment conditions caused decreases in NL-20 cell viability (e.g., viability decreased to 12.0% after parathion-methyl treatment, to 14.7% after azinphos-methyl treatment, and to 6.9% after omethoate treatment). Similar to the Ames test, all of the insecticides showed decreased toxicity in human cells when they were cultured in the presence of plant metabolism. In conclusion, when the studied organophosphorus insecticides were plant-metabolized, they induced mutations in the bacterial strain TA98. In human cell lines, plant metabolism reduced the cytotoxic properties of the insecticides, and human keratinocytes were more resistant to mortality than bronchial cells.