Project description:N-nitroso compounds (NOC) may be implicated in human colon carcinogenesis, but the toxicological mechanisms involved have not been elucidated. Since it was previously demonstrated that nitrosamines and nitrosamides, representing two classes of NOC, induce distinct gene expression effects in colon cells that are particularly related to oxidative stress, we hypothesized that different radical mechanisms are involved. Using ESR spectroscopy, we investigated radical generating properties of genotoxic NOC concentrations in human colon adenocarcinoma cells (Caco-2). Cells were exposed to nitrosamides (N-methyl-N'-nitro-N-nitrosoguanidine, N-methyl-N-nitrosurea) or nitrosamines (N-nitrosodiethylamine, N-nitrosodimethylamine, N-nitrosopiperidine, N-nitrosopyrrolidine). Nitrosamines caused formation of reactive oxygen species (ROS) and carbon centered radicals which was further stimulated in presence of Caco-2 cells. N-methyl-N-nitrosurea exposure resulted in a small ROS signal, and formation of nitrogen centered radicals (NCR), also stimulated by Caco-2 cells. N-methyl-N'-nitro-N-nitrosoguanidine did not cause radical formation at genotoxic concentrations, but at increased exposure levels, both ROS and NCR formation was observed. By associating gene expression patterns with ROS formation, several cellular processes responding to nitrosamine exposure were identified, including apoptosis, cell cycle blockage, DNA repair and oxidative stress. These findings suggest that following NOC exposure in Caco-2 cells, ROS formation plays an important role in deregulation of gene expression patterns which may be relevant for the process of chemical carcinogenesis in the human colon, in addition to the role of DNA alkylation. Keywords: Nitrosamines, nitrosamides, N-nitroso compounds, free radicals, toxicogenomics, colon carcinogenesis

Project description:N-nitroso compounds (NOC) are genotoxic compounds and animal carcinogens, and may play a role in human cancer development. Since the gastro-intestinal tract is an important route of exposure, we hypothesize that NOC exposure targets genetic processes relevant in colon carcinogenesis. To investigate this, we analysed the transcriptomic effects of genotoxic concentrations of two nitrosamides, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG, 1µM) and N-methyl-N-nitrosurea (MNU, 1mM), and four nitrosamines, N-nitrosodiethylamine (NDEA, 50mM), N-nitrosodimethylamine (NDMA, 100mM), N-nitrosopiperidine (NPIP, 40mM), and N-nitrosopyrrolidine (NPYR, 100mM), in the human colon carcinoma cell line Caco-2. Gene Ontology gene group, consensus motif gene group and biological pathway analysis revealed that nitrosamides had little effect on gene expression after 24 hours of exposure, whereas nitrosamines had a strong impact on the transcriptomic profile. Analyses showed modifications of cell cycle regulation and apoptosis pathways for nitrosamines which was supported by flow cytometric analysis. We found additional modifications in gene groups and pathways of oxidative stress and inflammation, which suggest an increase in oxidative stress and pro-inflammatory immune response upon nitrosamine exposure, although less distinct for NDMA. Furthermore, NDEA, NPIP and NPYR most strongly affected several developmental motif gene groups and pathways, which may influence developmental processes. Many of these pathways and gene groups are implicated in the carcinogenic process and their modulation by nitrosamine exposure may therefore influence the development of colon cancer. In summary, our study has identified pathway modifications in human colon cells which may be associated with cancer risk of nitrosamine exposure in the human colon. Keywords: Comparison of genome-wide gene expression between different conditions The study investigated differential gene expression in Caco-2 cell line mRNA following 24 hours of exposure to six different N-nitroso compounds. Four biological replicates per sample compound. One compound per array, hybridized against vehicle control. Dye-swap between biological replicates 1 and 2, and 3 and 4.

Project description:N-nitroso compounds (NOC) are genotoxic compounds and animal carcinogens, and may play a role in human cancer development. Since the gastro-intestinal tract is an important route of exposure, we hypothesize that NOC exposure targets genetic processes relevant in colon carcinogenesis. To investigate this, we analysed the transcriptomic effects of genotoxic concentrations of two nitrosamides, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG, 1µM) and N-methyl-N-nitrosurea (MNU, 1mM), and four nitrosamines, N-nitrosodiethylamine (NDEA, 50mM), N-nitrosodimethylamine (NDMA, 100mM), N-nitrosopiperidine (NPIP, 40mM), and N-nitrosopyrrolidine (NPYR, 100mM), in the human colon carcinoma cell line Caco-2. Gene Ontology gene group, consensus motif gene group and biological pathway analysis revealed that nitrosamides had little effect on gene expression after 24 hours of exposure, whereas nitrosamines had a strong impact on the transcriptomic profile. Analyses showed modifications of cell cycle regulation and apoptosis pathways for nitrosamines which was supported by flow cytometric analysis. We found additional modifications in gene groups and pathways of oxidative stress and inflammation, which suggest an increase in oxidative stress and pro-inflammatory immune response upon nitrosamine exposure, although less distinct for NDMA. Furthermore, NDEA, NPIP and NPYR most strongly affected several developmental motif gene groups and pathways, which may influence developmental processes. Many of these pathways and gene groups are implicated in the carcinogenic process and their modulation by nitrosamine exposure may therefore influence the development of colon cancer. In summary, our study has identified pathway modifications in human colon cells which may be associated with cancer risk of nitrosamine exposure in the human colon. Keywords: Comparison of genome-wide gene expression between different conditions

Project description:Study 1: Transcriptomic profiles in colon tissue from inflammatory bowel diseases patients in relation to N-nitroso compound exposure and colorectal cancer risk Study 1: N-nitroso compounds (NOC) have been suggested to play a role in human cancer development but definitive evidence is still lacking. In this study we investigated gene expression modifications induced in human colon tissue in relation to NOC exposure to gain insight in the relevance of these compounds in human colorectal cancer (CRC) development. Since there are indications that inflammation stimulates endogenous NOC formation, the study population consisted of patients with inflammatory bowel disease (IBD) and irritable bowel syndrome patients as controls without inflammation. Strong transcriptomic differences were identified in colonic biopsies from IBD patients and compared to controls that enhance the understanding of IBD pathophysiology. However, fecal NOC levels were not increased in IBD patients, suggesting that inflammation did not stimulate NOC formation. By relating gene expression changes of all subjects to fecal NOC levels, we did, however, identify a NOC exposure-associated transcriptomic response that suggests that physiological NOC concentrations may induce genotoxic responses and chromatin modifications in human colon tissue, both of which are linked to carcinogenicity. In a network analysis, chromatin modifications were linked to 11 significantly modulated histone genes, pointing towards a possible epigenetic mechanism that may be relevant in comprehending the molecular basis of NOC-induced carcinogenesis. We conclude that NOC exposure is associated with gene expression modifications in the colon that may increase CRC risk in humans. Study 2: Red meat intake-induced increases in fecal water genotoxicity correlate with pro-carcinogenic gene expression changes in the human colon Study 2: Red meat consumption is associated with an increased colorectal cancer (CRC) risk, which may be due to an increased endogenous formation of genotoxic N-nitroso compounds (NOCs). To assess the impact of red meat intake on potential risk factors of CRC, we investigated the effect of a 7-day dietary red meat intervention in human subjects on endogenous NOC formation and fecal water genotoxicity in relation to transcriptomic changes induced in colonic tissue. In order to evaluate the potential effect of an inflamed colon on endogenous nitrosation, the study population consisted of inflammatory bowel disease (IBD) and irritable bowel syndrome (IBS) control subjects without inflammation. The intervention had no effect on fecal NOC formation but fecal water genotoxicity significantly increased in response to red meat intake. Since IBD patients showed no difference in fecal NOC formation or fecal water genotoxicity levels as compared to IBS controls, for transcriptomic analyses, all subjects were grouped together. Genes significantly correlating with the increase in fecal water genotoxicity were involved in biological pathways indicative of genotoxic effects, including modifications in DNA damage, cell cycle, and apoptosis pathways. Moreover, WNT signaling and nucleosome remodeling pathways were modulated that are known to play a part in the carcinogenic process in the human colon. These results are in line with a possible oxidative effect of dietary heme. We conclude that the gene expression changes identified in this study corroborate the genotoxic potential of diets high in red meat and point towards a possible risk of CRC development in humans. The study investigated transcription levels in human colon biopsies obtained during a colonoscopic exam in 32 subjects suffering from either inflammatory bowel disease (IBD) or irritable bowel syndrome (IBS). IBS patients served as control patients for comparison with IBD patients (see Study 1). 12 of these patients (6 IBD and 6 IBS) also followed a 7-day diet high in red meat (300 grams/day) after which a second colonscopic exam was performed to obtain colon biopsies to investigate the effect of the red meat intervention (Study 2). For each subject, cRNA copies of mRNA isolated from the colon biopsies were labeled with one dye (Cy3) and each sample was hybridized on a separate array. One replicate per subject or before/after red meat intervention (so 44 arrays in total, i.e. 20 before patients and 12 before and after patients).

Project description:N-nitroso compounds (NOCs) can be formed through endogenous nitrosation in the human body and are known to induce micronuclei (MN) formation in vitro. Since lymphocytic MN represent a well-validated biomarker of effect with regard to carcinogenic risk in multiple target organs, establishing a link between NOCs and MN in humans could provide evidence for a carcinogenic risk. Investigating gene expression modulations in relation to NOC exposure could provide further crucial information on underlying molecular mechanisms-of-action. The purpose of this study is therefore to establish the relationship between human NOC exposure under daily life conditions and MN formation in relation to associated transcriptomic changes, using lymphocytes as a surrogate tissue for analyzing carcinogenic events in target organs. We analyzed gene expression levels and MN frequency in lymphocytes from adults participating in a European cohort from the multidisciplinary research project NewGeneris. For assessing exposure to NOCs, urinary samples were analyzed for marker nitrosamines by GC-MS. NOC exposure was subsequently linked to peripheral blood transcriptomics. We found an association between MN frequency and urinary NOCs, indicating that NOC exposure under daily life circumstances may play an important role in human cancer development. Furthermore, we have identified modifications in pathways which indicate a molecular response to NOC-induced genotoxicity. From this, we derived a small group of genes which could be suitable as mechanistic-based transcriptomic biomarkers of NOC exposure-related cancer risk. The modified genetic processes and genes found in this study may be of interest for future investigations into NOC-associated carcinogenicity in humans. The study investigated transcription levels in human whole blood from 30 pregnant mothers in a Danish NewGeneris cohort. For each subject, cRNA copies of isolated mRNA were labeled with one dye (Cy3) and each sample was hybridized on separate arrays. One replicate per subject (so 30 arrays in total).

Project description:Study 1: Transcriptomic profiles in colon tissue from inflammatory bowel diseases patients in relation to N-nitroso compound exposure and colorectal cancer risk Study 1: N-nitroso compounds (NOC) have been suggested to play a role in human cancer development but definitive evidence is still lacking. In this study we investigated gene expression modifications induced in human colon tissue in relation to NOC exposure to gain insight in the relevance of these compounds in human colorectal cancer (CRC) development. Since there are indications that inflammation stimulates endogenous NOC formation, the study population consisted of patients with inflammatory bowel disease (IBD) and irritable bowel syndrome patients as controls without inflammation. Strong transcriptomic differences were identified in colonic biopsies from IBD patients and compared to controls that enhance the understanding of IBD pathophysiology. However, fecal NOC levels were not increased in IBD patients, suggesting that inflammation did not stimulate NOC formation. By relating gene expression changes of all subjects to fecal NOC levels, we did, however, identify a NOC exposure-associated transcriptomic response that suggests that physiological NOC concentrations may induce genotoxic responses and chromatin modifications in human colon tissue, both of which are linked to carcinogenicity. In a network analysis, chromatin modifications were linked to 11 significantly modulated histone genes, pointing towards a possible epigenetic mechanism that may be relevant in comprehending the molecular basis of NOC-induced carcinogenesis. We conclude that NOC exposure is associated with gene expression modifications in the colon that may increase CRC risk in humans. Study 2: Red meat intake-induced increases in fecal water genotoxicity correlate with pro-carcinogenic gene expression changes in the human colon Study 2: Red meat consumption is associated with an increased colorectal cancer (CRC) risk, which may be due to an increased endogenous formation of genotoxic N-nitroso compounds (NOCs). To assess the impact of red meat intake on potential risk factors of CRC, we investigated the effect of a 7-day dietary red meat intervention in human subjects on endogenous NOC formation and fecal water genotoxicity in relation to transcriptomic changes induced in colonic tissue. In order to evaluate the potential effect of an inflamed colon on endogenous nitrosation, the study population consisted of inflammatory bowel disease (IBD) and irritable bowel syndrome (IBS) control subjects without inflammation. The intervention had no effect on fecal NOC formation but fecal water genotoxicity significantly increased in response to red meat intake. Since IBD patients showed no difference in fecal NOC formation or fecal water genotoxicity levels as compared to IBS controls, for transcriptomic analyses, all subjects were grouped together. Genes significantly correlating with the increase in fecal water genotoxicity were involved in biological pathways indicative of genotoxic effects, including modifications in DNA damage, cell cycle, and apoptosis pathways. Moreover, WNT signaling and nucleosome remodeling pathways were modulated that are known to play a part in the carcinogenic process in the human colon. These results are in line with a possible oxidative effect of dietary heme. We conclude that the gene expression changes identified in this study corroborate the genotoxic potential of diets high in red meat and point towards a possible risk of CRC development in humans.

Project description:N-nitroso compounds (NOCs) can be formed through endogenous nitrosation in the human body and are known to induce micronuclei (MN) formation in vitro. Since lymphocytic MN represent a well-validated biomarker of effect with regard to carcinogenic risk in multiple target organs, establishing a link between NOCs and MN in humans could provide evidence for a carcinogenic risk. Investigating gene expression modulations in relation to NOC exposure could provide further crucial information on underlying molecular mechanisms-of-action. The purpose of this study is therefore to establish the relationship between human NOC exposure under daily life conditions and MN formation in relation to associated transcriptomic changes, using lymphocytes as a surrogate tissue for analyzing carcinogenic events in target organs. We analyzed gene expression levels and MN frequency in lymphocytes from adults participating in a European cohort from the multidisciplinary research project NewGeneris. For assessing exposure to NOCs, urinary samples were analyzed for marker nitrosamines by GC-MS. NOC exposure was subsequently linked to peripheral blood transcriptomics. We found an association between MN frequency and urinary NOCs, indicating that NOC exposure under daily life circumstances may play an important role in human cancer development. Furthermore, we have identified modifications in pathways which indicate a molecular response to NOC-induced genotoxicity. From this, we derived a small group of genes which could be suitable as mechanistic-based transcriptomic biomarkers of NOC exposure-related cancer risk. The modified genetic processes and genes found in this study may be of interest for future investigations into NOC-associated carcinogenicity in humans.

Project description:Study hypothesis: We hypothesise that both colon inflammation and a diet high in red meat increase the endogenous formation of potentially carcinogenic N-nitroso compounds in the human colon and that these compounds increase the colorectal cancer risk, which could (partially) explain the increased colorectal cancer risk that is associated with inflammatory bowel disease and diets high in red meat. Inflammatory bowel disease is characterised by a chronic inflammation within the gastrointestinal tract, which, in case of ulcerative colitis, is present in the colon and rectum. Primary outcome(s): 1. Whole genome gene expression modifications by microarray analysis (4x44K Agilent platform) 2. Apparent total nitroso compounds in faecal matter by thermal energy analysis 3. Faecal water genotoxicity (30 minute exposure to 10% faecal water) by comet assay analysis in the adenocarcinoma cell line Caco-2 All outcomes are measured at baseline and post intervention.

Project description:Global Gene Expression Analysis Reveals Differences in Cellular Responses to Hydroxyl- and Superoxide-induced Oxidative Stress in Caco-2 Cells. Reactive oxygen species-induced oxidative stress in the colon is involved in inflammatory bowel diseases and is suggested to be associated with colorectal cancer risk. However, our insight in molecular responses to different oxygen radicals is still fragmentary. Therefore, we studied global gene expression by an extensive time serie (0.08, 0.25, 0.5, 1, 2, 4, 8, 16, or 24 hours ) analyses in human colon cancer (Caco-2) cells after exposure to H2O2 or menadione, leading to the formation of HO. or O2.- radicals respectively. Next to gene expression, induction of pathways and correlations with related phenotypic markers (oxidative DNA damage, cell cycle arrest) was investigated. Gene expression analysis resulted in 1404 differentially expressed genes upon H2O2 challenge and 979 genes after menadione treatment. Time-dependent co-regulated genes immediately showed a pulse-like response to HO. formation while the O2.--induced expression is not restored over 24 hours. Pathway analyses demonstrated that the difference in the modulation of gene expression is also reflected in regulation of pathways by HO. and O2.-: H2O2 immediately influences pathways involved in the immune function, while menadione constantly regulated cell cycle-related pathways. Altogether, this study offers a novel and detailed insight in differential time-dependent oxidative stress response, but most importantly, shows that effects of HO. and O2.- can also be discriminated regarding their modulation of particular carcinogenesis-related mechanisms. Keywords: Comparison of genome-wide gene expression between different time points for H2O2 and menadione.

Project description:Molecular signatures of N-nitroso compounds in Caco-2 cells: implications for colon carcinogenesis