Isolation of leukocytes from frozen buffy coat for comet assay analysis of DNA damage.

Frozen buffy coat fractions are often stored in human biomonitoring trials but their use for biomarker purposes has been limited. The purpose of the current study was to study whether frozen buffy coats can be used to monitor DNA damage levels. EDTA blood samples were provided from 9 healthy, non-smoking female volunteers, aged 26-48. Pre-existing DNA damage (strand breaks and oxidised purines) was measured with the comet assay in thawed resuspended buffy coat samples and washed leukocytes from these buffy coats, as well as resistance to DNA damage induced exogenously by H2O2 in the latter, and compared with damage measured in peripheral blood mononuclear cells isolated from fresh blood using percoll gradient centrifugation. Basal DNA damage levels (strand breaks) were significantly higher in the leukocytes isolated from frozen buffy coats in the untreated samples compared with peripheral blood mononuclear cells. However, the levels of strand breaks were still low (<4% tail DNA), indicating that little damage is caused by freezing or processing. Base oxidation was significantly higher in isolated buffy coat leukocytes than in peripheral blood mononuclear cells from fresh blood, but showed a good correlation (r = 0.67) between the two cell types. The correlation for strand breaks was stronger (r = 0.85). H2O2 induced DNA breaks in the cells both from fresh blood and buffy coats. The results indicate that buffy coat samples stored from cohort studies might be usefully analysed for DNA damage in retrospective epidemiological investigations. However, caution should be exercised when comparing the absolute levels of DNA damage in buffy coat leukocytes and peripheral blood mononuclear cells.

Consumption of a dark roast coffee blend reduces DNA damage in humans: results from a 4-week randomised controlled study.

PURPOSE: To determine the DNA protective effects of a standard coffee beverage in comparison to water consumption. METHODS: The single-blind, randomised controlled study with parallel design included healthy women (n = 50) and men (n = 50) recruited from the general Central European population. The subjects were randomised in a coffee and a control group, with stratification for sex and body mass index. The study comprised two periods of 4 weeks: a preconditioning period, with daily consumption of at least 500 ml water but no coffee, nor tea, nor any other caffeine-containing product. During the subsequent intervention period the coffee group consumed 500 ml of freshly brewed dark roast coffee blend per day, the control group consumed water instead. On the last day of each period, blood was drawn and analysed by comet assay (single-cell gel electrophoresis) to assess the level of DNA damage (strand breakage). RESULTS: At the end of the intervention period the mean level of DNA strand breaks in the coffee group has decreased in comparison to the control group [difference in means 0.23% TI (tail intensity), p = 0.028]. The mean change from baseline (delta value) was - 23% in the coffee group (p = 0.0012). Effects of coffee intake were similar for men and women. During intervention, neither group showed any significant change in body weight or calorie intake. CONCLUSIONS: Our results indicate that regular consumption of a dark roast coffee blend has a beneficial protective effect on human DNA integrity in both, men and women.

Characterization of the proteome and lipidome profiles of human lung cells after low dose and chronic exposure to multiwalled carbon nanotubes.

The effects of long-term chronic exposure of human lung cells to multi-walled carbon nanotubes (MWCNT) and their impact upon cellular proteins and lipids were investigated. Since the lung is the major target organ, an in vitro normal bronchial epithelial cell line model was used. Additionally, to better mimic exposure to manufactured nanomaterials at occupational settings, cells were continuously exposed to two non-toxic and low doses of a MWCNT for 13-weeks. MWCNT-treatment increased ROS levels in cells without increasing oxidative DNA damage and resulted in differential expression of multiple anti- and pro-apoptotic proteins. The proteomic analysis of the MWCNT-exposed cells showed that among more than 5000 identified proteins; more than 200 were differentially expressed in the treated cells. Functional analyses revealed association of these differentially regulated proteins to cellular processes such as cell death and survival, cellular assembly, and organization. Similarly, shotgun lipidomic profiling revealed accumulation of multiple lipid classes. Our results indicate that long-term MWCNT-exposure of human normal lung cells at occupationally relevant low-doses may alter both the proteome and the lipidome profiles of the target epithelial cells in the lung.