Project description:"Liver represents one of the most important organs involved in the elimination of xenobiotic and potentially toxic substances. Cigarette smoke (CS) contains more than 7000 chemicals, among which compounds that exert biological effects and cause smoking-related diseases. Although CS is not directly hepatotoxic, a growing body of evidence suggests that it may exacerbate (pre-existing) chronic liver diseases. Here we integrated toxicological endpoints with molecular measurements and computational analysis approaches to investigate exposure effects on liver in an Apoe-/- mouse study. The mice were exposed to high concentrations of 3R4F reference CS (600 mg/m3 TPM, 29.9 mg/m3 nicotine), an aerosol from a candidate reduced risk product (RRP) the Tobacco Heating System (THS) 2.2 at matching nicotine concentration, or filtered air (Sham) for up to 8 months. THS2.2 was conceived using the heat-not-burn technology that heats tobacco avoiding pyrogenesis and pyrosynthesis. After 2 months of CS exposure, some groups were either switched to the RRP or underwent exposure cessation. While clear signs of hepatotoxic effects were absent for any exposure group, the integrative analysis of proteomics and transcriptomics data showed a CS-dependent impairment of specific biological networks, including lipid and xenobiotic metabolism, and iron homeostasis, which likely in turn mutually contribute to worsening of the oxidative stress. In contrast, most of these changes were absent in mice exposed to THS2.2, and in the cessation and switching groups. Our findings shed light on the complex biological response of the liver to CS exposure and support the benefits of switching to the tested heat-not-burn product, THS2.2."

Project description:Liver represents one of the most important organs involved in the elimination of xenobiotic and potentially toxic substances. Cigarette smoke (CS) contains several compounds that exert biological effects and cause smoking related diseases. Although cigarette smoke is not directly hepatotoxic, a growing body of evidence suggests that CS may exacerbate chronic liver diseases. Here we integrated classical toxicological endpoints with molecular measurement and computational analysis approaches to investigate exposure effects on liver in an Apoe-/- mouse study. The mice were exposed to high concentrations of 3R4F reference CS (600 mg/m3 TPM, 29.9 mg/m3 nicotine), aerosol from a candidate modified risk tobacco product (MRTP), the Tobacco Heating System (THS) 2.2, or filtered air (Sham) for up to 8 months. After 2 months of CS exposure, some groups were either switched to the MRTP or underwent cessation. While clear signs of hepatotoxic effects were absent for any exposure group, the integrative analysis of proteomic and transcriptomic data showed a CS-dependent impairment of specific biological networks, such as lipid, xenobiotic, and iron homeostasis, which likely in turn mutually contribute to worsening of the oxidative stress. In contrast, most of these changes were absent in mice exposed to THS2.2, and in the cessation and in the switching groups. Our findings shed light on the complex biological response of the liver to CS exposure and support the benefits of switching to the tested heat-not-burn product, THS2.2.

Project description:Cigarette smoke (CS) causes adverse health effects and, for smoker who do not quit, modified risk tobacco products (MRTPs) can be an alternative to reduce the risk of developing smoking-related diseases. Standard toxicological endpoints can lack sensitivity, with systems toxicology approaches yielding broader insights into toxicological mechanisms. In a 6-month systems toxicology study on ApoE-/- mice, we conducted an integrative multi-omics analysis to assess the effects of aerosols from the Carbon Heated Tobacco Product (CHTP) 1.2 and Tobacco Heating System (THS) 2.2-a potential and a candidate MRTP based on the heat-not-burn (HnB) principle-compared with CS at matched nicotine concentrations. Molecular exposure effects in the lungs were measured by mRNA/microRNA transcriptomics, proteomics, metabolomics, and lipidomics. Integrative data analysis included Multi-Omics Factor Analysis and multi-modality functional network interpretation. Across all five data modalities, CS exposure was associated with an increased inflammatory and oxidative stress response, and lipid/surfactant alterations. Upon HnB aerosol exposure these effects were much more limited or absent, with reversal of CS-induced effects upon cessation and switching to CHTP 1.2. Functional network analysis revealed CS-induced complex immunoregulatory interactions across the investigated molecular layers (e.g., itaconate, quinolinate, and miR-146) and highlighted the engagement of the heme-Hmox-bilirubin oxidative stress axis by CS. This work exemplifies how multi-omics approaches can be leveraged within systems toxicology studies and the generated multi-omics data set can facilitate the development of analysis methods and can yield further insights into the effects of toxicological exposures on the lung of mice.

Project description:Cigarette smoke (CS) causes adverse health effects and leads to the development of respiratory disease (chronic obstructive pulmonary disease), cardiovascular disease, and cancer. To reduce the risk of smokers developing smoking-related diseases, Philip Morris International is developing modified risk tobacco products (MRTP). Within a systems toxicology study, we conducted an integrative multi-omics analysis to assess the effects of aerosols from two potential MRTPs - the Carbon Heated Tobacco Product (CHTP) 1.2 and the Tobacco Heating System (THS) 1.2 -, compared with cigarette smoke (CS) at matched nicotine concentrations, on the lung of ApoE-/- mice. Mice were exposed for up to six months and molecular exposure effects were measured by mRNA/miRNA transcriptomics, proteomics, metabolomics, and lipidomics. In addition, the impact of cessation (CESS) or switching to CHTP 1.2 (SWITCH) after three months of CS exposure was evaluated. This data set represents the lung metabolomics data obtained after 3 and 6 months of exposure. The 'Animal ID' or 'CAN' represents the unique animal identifier and allows matching of samples across the different data modalities.

Project description:Smoke from conventional cigarettes (C-cigarettes) contains various reactive oxygen species and toxic chemicals, which potentially cause oxidative damage not only to airways but also to the whole body, leading eventually to diseases, including emphysema, advanced atherosclerosis, and cancer. Many heat-not-burn tobacco products (HTPs) have been commercialized recently in Japan to maintain the smoking population by advertising that HTPs are less toxic. However, there were few studies reported from neutral organizations whether HTPs are indeed less damaging. To evaluate the potential capacity of HTPs to induce oxidative stress, we here compared two different HTPs with two types of C-cigarettes, using human fibroblast IMR90SV cells and 5% aqueous extracts in 10-ml phosphate-buffered saline (50-ml smoke/10 s). HTPs exhibited significantly lower oxidative toxicity in comparison to C-cigarettes. Whereas C-cigarettes induced ferroptosis in fibroblasts, the effects of HTPs were significantly reduced by measuring the levels of peroxides, pro-inflammatory cytokine expression, autophagy, catalytic Fe(II) and 8-hydroxy-2'-deoxyguanosine. Notably, major portions of C-cigarettes-induced pathogenic responses were inhibited by catalase. However, HTPs still induced p62 autophagy-adaptor at 5%-dilution and caused lethal effects to fibroblasts with undiluted solution. In conclusion, HTPs smoke per se can be toxic despite less toxicity in comparison to C-cigarettes, which warrants further investigation.

Project description:Although smoking cessation shows clear cardiovascular risk benefits, lung-related disease risk remains higher in former smokers than in never smokers. To better understand the factors involved in this phenomenon, ApoE-/- mice were exposed to mainstream cigarette smoke (CS) or a smoking cessation-mimicking protocol for up to six months. Analysis of bronchoalveolar lavage fluid (BALF) from CS-exposed ApoE-/- mice revealed the presence of high concentrations of mediators involved in functions ranging from inflammation to cell proliferation and tissue remodeling. Gene expression levels for many analytes found elevated in BALF were also increased in lung tissue, indicating that the inflammatory response was the result of local tissue activation and the contribution of recruited inflammatory cells. Gene set enrichment analysis (GSEA) of expression data from lungs of CS-exposed mice showed activation of pathways involved in cell proliferation and tissue remodeling and a progressive deactivation upon smoke exposure cessation. Distinct activation patterns of inflammation, complement, and xenobiotic metabolism pathways were found in nasal epithelium and lung parenchyma during CS exposure and smoking cessation. Exposure of ApoE-/- mice to CS for up to 6 months induced adaptive and inflammatory responses in the respiratory tract that were partially deactivated upon cessation. We were able to reveal molecular perturbations accompanying these changes during CS exposure and cessation. Differential CS-mediated responses of pulmonary and nasal tissues reflect common mechanisms but also the varying degrees of epithelial functional specialization along the respiratory tract. These findings provide novel clues for the identification of markers of COPD progression.

Project description:Using an in vitro human small airway epithelium model, we assessed the biological impact of an aerosol from a candidate modified-risk tobacco product, the tobacco heating system (THS) 2.2, to investigate the potential reduced risk of THS2.2 aerosol exposure compared with cigarette smoke. Following the recommendations of the Institute of Medicine and the Tobacco Product Assessment Consortium, in which modified-risk tobacco products assessment should be performed in comparison with standard conventional products, the effects of the THS2.2 aerosol exposure on the small airway cultures were compared with those of 3R4F cigarette smoke. We used a systems toxicology approach whereby elucidation of toxic effects is derived not only from functional assay readouts but also from omics technologies. Cytotoxicity, ciliary beating function, secretion of pro-inflammatory mediators and histological assessment represented functional assays. The omics data included transcriptomic and miRNA profiles. Exposure-induced perturbations of causal biological networks were computed from the transcriptomic data. The results showed that THS2.2 aerosol exposure at the tested doses elicited lower cytotoxicity levels and lower changes in the secreted pro-inflammatory mediators than 3R4F smoke. Although THS2.2 exposure elicited alterations in the gene expression, a higher transcriptome-induced biological impact was observed following 3R4F smoke: The effects of THS2.2 aerosol exposure, if observed, were mostly transient and diminished more rapidly after exposure than those of 3R4F smoke. The study demonstrated that the systems toxicology approach can reveal changes at the cellular level that would be otherwise not detected from functional assays, thus increasing the sensitivity to detect potential toxicity of a treatment/exposure.

Project description:Modern 'omic' technologies, where changes in the expression of thousands of molecular species can be investigated in even a simple experiment, provide contemporary biomedical researchers with an unprecedented level of molecular granularity. An outstanding challenge is transformation of this experimental detail and complexity into meaningful biological insight. This is especially true for drug development and toxicological risk assessment, where molecular profiling data is increasingly being used to investigate the biological effects of a variety of exposures, from drugs to environmental factors, on human systems. Recently, we proposed a systems-based strategy for objectively predicting the mechanistic impact of biologically active substances from transcriptomic data, and report here on an initial implementation of this strategy. We applied a set of biological network models and novel scoring algorithms to investigate transcriptomic data from a range of experimental systems. Importantly, this approach enabled continuity between investigation at the molecular, pathway, and systems levels. For both in vitro systems with simple exposures and in vivo systems with complex exposures, the method was able to identify and provide relative quantitation for the precise mechanisms that were impacted. For example, when applied to data from mice exposed to cigarette smoke, the methodology correctly identified known mechanistic effects of the exposure, including increased pulmonary inflammation, necrosis, and proliferation. Importantly, many of the effects indicated by the methodology were supported by experimental endpoint data, providing further objective validation of the general approach. We propose that various fields of human disease research, from drug development to consumer product testing, could benefit from using this or similar approaches to evaluate the biological impact of exposures.

Project description:IntroductionUS law requires disclosure of quantities of toxic chemicals (constituents) in cigarette smoke by brand and sub-brand. This information may drive smokers to switch to cigarettes with lower chemical quantities, under the misperception that doing so can reduce health risk. We sought to understand past brand-switching behavior and whether learning about specific chemicals in cigarette smoke increases susceptibility to brand switching.MethodsParticipants were US adult smokers surveyed by phone (n = 1,151, probability sample) and online (n = 1,561, convenience sample). Surveys assessed whether smokers had ever switched cigarette brands or styles to reduce health risk and about likelihood of switching if the smoker learned their brand had more of a specific chemical than other cigarettes. Chemicals presented were nicotine, carbon monoxide, lead, formaldehyde, arsenic, and ammonia.ResultsPast brand switching to reduce health risk was common among smokers (43% in phone survey, 28% in online survey). Smokers who were female, over 25, and current "light" cigarette users were more likely to have switched brands to reduce health risks (all p < .05). Overall, 61-92% of smokers were susceptible to brand switching based on information about particular chemicals. In both samples, lead, formaldehyde, arsenic, and ammonia led to more susceptibility to switch than nicotine (all p < .05).ConclusionsMany US smokers have switched brands or styles to reduce health risks. The majority said they might or would definitely switch brands if they learned their cigarettes had more of a toxic chemical than other brands. Brand switching is a probable unintended consequence of communications that show differences in smoke chemicals between brands.

Project description:OBJECTIVES:There is no safe or risk-free level of tobacco use or tobacco smoke exposure. In this randomized controlled trial, we tested a tobacco control intervention in families and specifically evaluated a tailored cessation intervention for the parents and/or caregivers (Ps/Cs) who were smokers while their children were simultaneously enrolled in tobacco prevention. METHODS:Ps/Cs and children were recruited from 14 elementary schools across rural and urban settings. Approximately one-fourth (24.3%; n = 110) of the total Ps/Cs enrolled in the randomized controlled trial (n = 453) were smokers, predominantly women (80.9%), with a mean age of 37.7 years. (SD 12.2); 62.7% were African American, 44% had less than a high school education, and 58% earned <$20 000 annually. P/C smokers were offered a tailored cessation intervention in years 1 and 2. Self-report smoking status and saliva cotinine were obtained at baseline, the end of treatment (EOT) and/or year 2, and in the year 4 follow-up. RESULTS:Ps/Cs in the intervention group showed a larger increase in self-reported smoking abstinence over time (EOT: 6.5% [SE = 5.7%]; year 4: 40.6% [SE = 5.7%]) than the control group (EOT: 0.0% [SE = 6.5%]; year 4: 13.2% [SE = 6.4%]; F = 4.82; P = .0306). For cotinine, the intervention group showed a decrease from baseline (239.9 [SE = 1.3]) to EOT 99.3 [SE = 1.4]) and then maintenance through year 4 (109.6 [SE = 1.4]), whereas the control group showed increases from baseline (221.1 [SE = 1.4]) to EOT (239.0 [SE = 1.4]) to year 4 (325.8 [SE = 14]; F = 5.72; P = .0039). CONCLUSIONS:This study provides evidence that tailored cessation offered to Ps/Cs in their children's schools during their children's enrollment in tobacco prevention may contribute to more robust success in P/C cessation and a reduction of tobacco smoke exposure in children.