Betsy R. Bombick

Inhibition of mutagenicity of N-nitrosamines by tobacco smoke and its constituents

Tobacco smoke is a complex chemical mixture including pyridine alkaloids and N-nitrosamines, with the concentration of the former several orders of magnitude higher that that of the N-nitrosamines. The major biologically important N-nitrosamines present in tobacco smoke are N-nitrosodimethylamine (NDMA), 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N(1)-nitrosonornicotine (NNN). These nitrosamines require metabolic activations by cytochrome P-450s for the expression of mutagenicity. Although nicotine, the major pyridine alkaloid in tobacco, has been shown to inhibit the metabolic activation of NNK, its effect on the mutagenicity of NNK and other N-nitrosamines has not been reported, In the present study, the ability of three pyridine alkaloids (nicotine, cotinine, nornicotine) and aqueous cigarette smoke condensate extract (ACE) to inhibit the mutagenicity of tobacco-related N-nitrosamines was tested on Salmonella typhimurium strain TA1535 in the presence of a metabolic activation system (S9). All three of the pyridine alkaloids tested, as well as ACE, inhibited the mutagenicity of NDMA and NNK, but not NNN, in a concentration-dependent manner. The induction of SCEs in mammalian cells (CHO) by NNK in the presence of metabolic activation was also significantly reduced by nicotine and cotinine. None of the observed reductions in mutagenicity could be explained by cytotoxicity. These results demonstrate that tobacco smoke contains chemicals, pyridine alkaloids and other unidentified constituent(s), which inhibit the mutagenicity of N-nitrosamines.

Effect of pyrolysis temperature on the mutagenicity of tobacco smoke condensate.

Tobacco smoke aerosols with fewer mutagens in the particulate fraction may present reduced risk to the smoker. The objective of this study was to test the hypothesis that the temperature at which tobacco is pyrolyzed or combusted can affect the mutagenicity of the particulate fraction of the smoke aerosol. Tobacco smoke aerosol was generated under precisely controlled temperature conditions from 250 to 550 degrees C by heating compressed tobacco tablets in air. The tobacco aerosols generated had a cigarette smoke-like appearance and aroma. The tobacco smoke aerosol was passed through a Cambridge filter pad to collect the particulate fraction, termed the smoke condensate. Although condensates of tobacco smoke and whole cigarette mainstream smoke share many of the same chemical components, there are physical and chemical differences between the two complex mixtures. The condensates from smoke aerosols prepared at different temperatures were assayed in the Ames Salmonella microsome test with metabolic activation by rat liver S9 using tester strains TA98 and TA100. Tobacco smoke condensates were not detectably mutagenic in strain TA98 when the tobacco smoke aerosol was generated at temperatures below 400 degrees C. Above 400 degrees C, condensates were mutagenic in strain TA98. Similarly, condensates prepared from tobacco smoke aerosols generated at temperatures below 475 degrees C were not detectably mutagenic in strain TA100. In contrast, tobacco tablets heated to temperatures of 475 degrees C or greater generated smoke aerosol that was detectably mutagenic as measured in TA100. Therefore, heating and pyrolyzing tobacco at temperatures below those found in tobacco burning cigarettes reduces the mutagenicity of the smoke condensate. Highly mutagenic heterocyclic amines derived from the pyrolysis of tobacco leaf protein may be important contributors to the high temperature production of tobacco smoke Ames Salmonella mutagens. The relevance of these findings regarding cancer risk in humans is difficult to assess because of the lack of a direct correlation between mutagenicity in the Ames Salmonella test and carcinogenicity.

Distinct regulatory profiles of interleukins and chemokines in response to cigarette smoke condensate in normal human bronchial epithelial (NHBE) cells.

Bronchial epithelium is frequently exposed to air pollutants, and it is hypothesized that these cells elicit inflammatory responses as early elements in pulmonary defense. Our purpose was to evaluate changes in messenger RNA levels of 84 genes representing cytokines and receptors over a repetitive-exposure time course to further define the inflammatory responses associated with mainstream cigarette smoke (MSS) exposure in an in vitro lung model. Normal human bronchial epithelial cells were treated with mainstream cigarette smoke condensate (CSC) prepared from Kentucky 2R4F cigarettes (60 microg total particulate matter/mL media, 0.2% dimethylsulfoxide), and examined by quantitative real-time polymerase chain reaction. Applications of CSC were designed in seven groups to test immediate, early, intermediate, and late responses evaluated at the end of alternating exposure/recovery periods. Three predominant gene expression responses were observed: adaptive (return to baseline), sustained (maintained expression during treatment), and chronic (maintained expression posttreatment). Overall, 25 genes exhibited statistically significant changes: 14 genes exclusively elevated, 10 genes exclusively depressed, and 1, interleukin-8 (IL8), exhibiting both up- and downregulation in the seven groups. The most responsive genes were osteopontin (34-fold upregulation) and CXCL14 (23-fold downregulation). Our observations suggest that specific genes involved in inflammatory pathways respond to CSC in chronic, sustained, or adaptive patterns with the chronic pattern as the predominant behavior.

Toxicological Evaluation of Honey as an Ingredient Added to Cigarette Tobacco

A tiered testing strategy has been developed to evaluate the potential for new ingredients, tobacco processes, and technological developments to increase or reduce the biological activity that results from burning tobacco. In the manufacture of cigarettes, honey is used as a casing ingredient to impart both aroma and taste. The primary objective of this document is to summarize and interpret chemical and toxicological studies that have been conducted to evaluate the potential impact of honey on the biological activity of either mainstream cigarette smoke or cigarette smoke condensate. As part of ongoing stewardship efforts, cigarettes produced with honey (5% wet weight) as an alternative to invert sugar in tobacco casing material were subjected to extensive evaluation. Principal components of this evaluation were a determination of selected mainstream smoke constituent yields, Ames assay, sister chromatid exchange assay in Chinese hamster ovary cells, a 30-wk dermal tumor promotion evaluation of cigarette smoke condensate in SENCAR mice, and a 13-wk inhalation study of cigarette smoke in Sprague-Dawley rats. Comparative analytical evaluations demonstrated that the substitution of honey for invert sugar as a casing material in cigarettes had no significant impact on mainstream smoke chemistry. In addition, in vitro and in vivo studies demonstrated that cigarettes containing tobacco cased with honey had comparable biological activity to cigarettes containing invert sugar. Collectively, these data demonstrate that the use of honey as an alternative casing material in the manufacture of cigarettes does not alter the potential toxicity of cigarette smoke condensate (CSC) or cigarette smoke; therefore the use of honey as an ingredient added to cigarette tobacco is acceptable from a toxicological perspective.

Evaluation of cytotoxicity of different tobacco product preparations.

Acute exposure to cigarette smoke or its components triggers diverse cellular effects, including cytotoxicity. However, available data regarding the potential cytotoxic effects of smokeless tobacco (ST) extracts lack consensus. Here, we investigated the relative biological effects of 2S3 reference ST, and whether ST elicits differential cellular/molecular responses compared to combustible tobacco product preparations (TPPs) prepared from 3R4F cigarettes. Total particulate matter (TPM) and whole smoke conditioned medium (WS-CM) were employed as combustible TPPs, while the ST extract was used as non-combustible TPP. HL60, THP1 cells and human PBMCs were used to examine the effects of TPPs in short-term cell culture. Corresponding EC(50) values, normalized for nicotine content of the TPPs, suggest that combustible TPPs induced higher cytotoxicity as follows: WS-CM TPM ≥ ≫ST extract>nicotine. While all three TPPs induced detectable levels of DNA damage and IL8 secretion, the combustible TPPs were significantly more potent than the ST preparation. The major PBMC subsets showed differential cytotoxicity to combustible TPPs as follows: CD4>CD8>monocytes>NK cells. These findings suggest that, relative cytotoxic and other cell biological effects of TPPs are dose-dependent, and that ST extract is the least cytotoxic TPP tested in this study.

The time course of expression of genes involved in specific pathways in normal human bronchial epithelial cells following exposure to cigarette smoke.

This study was conducted to determine the time course of gene expression associated with specific signaling pathways in normal human bronchial epithelial (NHBE) cells after exposure to 2 concentrations of 2R4F tobacco mainstream smoke (MSS). Expression of 84 genes representing 18 signal transduction pathways was quantitated in MSS- and air-exposed cultures using real-time polymerase chain reaction (PCR) arrays at 1, 4, and 24 hours following exposure. A confidence score, calculated based on statistical analysis of the degree and reproducibility of expression changes, was used to identify potential biologically significant changes in gene expression. Stimulation of NIAP, an apoptosis inhibitor, suppression of NFKB1 and MYC, representing pro-apoptotic activity, and down-regulation of TCF7 and up-regulation of KLK2, representing anti-/pro-inflammatory responses, were altered 1 hour after exposure to the high concentration of MSS. At the 4-hour time point, the pattern had changed such that 10 different genes were now up-regulated and an additional gene was now down-regulated. Significant changes included genes involved in inflammatory response (LTA, SELPLG, and IL8), repair and wound-healing activity (MMP10), and growth activity (GREB1, EGR1), suggesting repair in this period. By 24 hours, the only up-regulated genes in common with the 4-hour profile were SELPLG and IL8, suggesting continued inflammatory signaling. These results suggest that identification of specific gene expression–based biomarkers of MSS toxicity is promising for investigating specific mechanisms of cellular damage. As expected, the expressed signals were dependent on the concentration of MSS and the postexposure times.

A summary of toxicological and chemical data relevant to the evaluation of cast sheet tobacco

A tiered testing strategy based on a comparative chemical and biological testing program has been developed to evaluate the potential of tobacco processes, ingredients, or other technological developments to change the biological activity that results from burning tobacco. Cast sheet tobacco is a specific type of reconstituted tobacco sheet that can be used in the manufacture of cigarettes. The comparative chemical and biological testing program was used to compare the mainstream smoke and cigarette smoke condensate (CSC) from a Reference cigarette that did not contain cast sheet to that collected from Test cigarettes containing cast sheet at a final blend level of either 10% or 15%. Testing included mainstream cigarette smoke chemistry studies, in vitro studies (Ames assay, sister chromatid exchange assay, and neutral red cytotoxicity assay), and in vivo toxicology studies (13-week rat nose-only inhalation assay and 30-week mouse dermal tumor promotion assay). Certain statistically significant differences were observed in the chemical and biological studies when the Reference cigarette was compared to each of the Test cigarettes. However, when viewed collectively, the chemical and biological studies demonstrated that inclusion of cast sheet up to 15% in the final blend did not increase the inherent biological activity of mainstream cigarette smoke or CSC.

Comparative study of DNA adduct formation in mice following inhalation of smoke from cigarettes that burn or primarily heat tobacco

The genotoxic potential of mainstream smoke from a test cigarette (TOB‐HT) that primarily heats tobacco and a representative tobacco‐burning cigarette (Kentucky reference 1R4F) was compared in male B6C3/F1 mice after nose‐only inhalation exposure. Mice were exposed 1 hr per day, 5 days/week for a 4 week period to mainstream smoke at concentrations of 0, 0.16, 0.32, and 0.64 mg total particulate matter/liter of air. Micronuclei formation in bone marrow and peripheral blood polychromatic erythrocytes (PCE) of animals exposed to either the TOB‐HT or 1R4F cigarette was not significantly different compared with control animals exposed nose‐only to filtered and humidified air (sham controls). DNA adduct measurement by the 32P‐postlabeling method indicated an exposure‐dependent increase in lung adducts of animals exposed to 1R4F cigarette smoke at all three concentrations with the mid and high exposure groups exhibitingstatistically significant increases (P < 0.05) in adduct formation compared to sham‐exposed animals. The concentration of DNA adducts in the lungs of animals exposed to the TOB‐HT cigarette was not significantly increased (P < 0.05) at any concentration compared to sham‐exposed controls. A statistically significant (P < 0.05) concentration‐dependent formation of DNA adducts was also observed in the heart tissues of animals exposed to smoke from the 1R4F cigarette at all three concentrations, but no significant increase in adduct formation was observed in heart DNA of the animals exposed to the TOB‐HT cigarette (P < 0.05). Under the conditions of this experiment, the mainstream smoke from the TOB‐HT cigarette was demonstrated to be less genotoxic in mice than mainstream smoke from the 1R4F cigarette, which is representative of cigarettes in the current U.S. market. Environ. Mol. Mutagen. 29:303‐311, 1997

Toxicological evaluation of dry ice expanded tobacco

A tiered testing strategy has been developed to evaluate the potential of tobacco processes, ingredients, or technological developments to change the biological activity resulting from burning tobacco. The strategy is based on comparative chemical and biological testing. Dry ice expanded tobacco (DIET) is an example of a common tobacco expansion process currently used in the manufacture of cigarettes to increase tobacco filling capacity. As part of the toxicological evaluation of DIET, test cigarettes containing DIET were compared with control cigarettes containing tobacco expanded with a traditional expansion agent (Freon-11, also known as trichlorofluoromethane). Testing included mainstream cigarette smoke chemistry studies, genotoxicity studies (Ames and sister chromatid exchange, SCE), a 13-week inhalation study in Sprague-Dawley rats, and a 30-week dermal tumor promotion study in SENCAR mice. Cigarettes containing DIET or Freon-11 expanded tobacco were similar in biological activity.

Toxicological evaluation of propane expanded tobacco

A tiered testing strategy has been developed to evaluate the potential for tobacco processes, ingredients, and other technological developments to increase or decrease the biological activity resulting from burning tobacco. The strategy is based on comparative chemical and biological testing. Propane expanded tobacco is an example of a processed tobacco used in the modern manufacture of cigarettes. Test cigarettes containing propane expanded tobacco were compared to control cigarettes containing tobacco expanded with a traditional expansion agent (Freon-11). The toxicological evaluation included chemistry studies using mainstream cigarette smoke (determination of selected constituent yields), in vitro studies using cigarette smoke condensate (Ames study in Salmonella typhimurium and sister chromatid exchange study in Chinese hamster ovary cells) and in vivo studies (13-week inhalation study of mainstream cigarette smoke in Sprague-Dawley rats and 30-week dermal tumor promotion study of cigarette smoke condensate in SENCAR mice). Although statistically significant differences in several smoke constituents were observed, most constituents from cigarettes containing 100% propane expanded tobacco were within market survey ranges. Furthermore, biological tests indicated that the cigarettes containing propane or Freon-11 expanded tobacco were not significantly different.