Michael Glei

Mechanisms of primary cancer prevention by butyrate and other products formed during gut flora-mediated fermentation of dietary fibre.

Dietary fibres are indigestible food ingredients that reach the colon and are then fermented by colonic bacteria, resulting mainly in the formation of short-chain fatty acids (SCFA) such as acetate, propionate, and butyrate. Those SCFA, especially butyrate, are recognised for their potential to act on secondary chemoprevention by slowing growth and activating apoptosis in colon cancer cells. Additionally, SCFA can also act on primary prevention by activation of different drug metabolising enzymes. This can reduce the burden of carcinogens and, therefore, decrease the number of mutations, reducing cancer risk. Activation of GSTs by butyrate has been studied on mRNA, protein, and enzyme activity level by real-time RT-PCR, cDNA microarrays, Western blotting, or photometrical approaches, respectively. Butyrate had differential effects in colon cells of different stages of cancer development. In HT29 tumour cells, e.g., mRNA GSTA4, GSTP1, GSTM2, and GSTT2 were induced. In LT97 adenoma cells, GSTM3, GSTT2, and MGST3 were induced, whereas GSTA2, GSTT2, and catalase (CAT) were elevated in primary colon cells. Colon cells of different stages of carcinogenesis differed in post-transcriptional regulatory mechanisms because butyrate increased protein levels of different GST isoforms and total GST enzyme activity in HT29 cells, whereas in LT97 cells, GST protein levels and activity were slightly reduced. Because butyrate increased histone acetylation and phosphorylation of ERK in HT29 cells, inhibition of histone deacetylases and the influence on MAPK signalling are possible mechanisms of GST activation by butyrate. Functional consequences of this activation include a reduction of DNA damage caused by carcinogens like hydrogen peroxide or 4-hydroxynonenal (HNE) in butyrate-treated colon cells. Treatment of colon cells with the supernatant from an in vitro fermentation of inulin increased GST activity and decreased HNE-induced DNA damage in HT29 cells. Additional animal and human studies are needed to define the exact role of dietary fibre and butyrate in inducing GST activity and reducing the risk of colon cancer.

Associations between dietary habits and body mass index with gut microbiota composition and fecal water genotoxicity: an observational study in African American and Caucasian American volunteers

BackgroundAfrican Americans (AA) suffer from an increased incidence and mortality of colorectal cancer (CRC). Environmental exposures including dietary habits likely contribute to a high burden of CRC, however, data on the dietary habits of AA is sparse. Diet might change the composition and the activities of the intestinal microbiota, in turn affecting fecal genotoxicity/mutagenicity that is thought to be associated with carcinogenesis.MethodsWe assessed dietary habits by food frequency questionnaire and by food records in 52 AA and 46 CA residents of the Eastern Shore of MD. Fecal microbiota composition was determined using 16S rRNA based methods and fecal genotoxicity measured using the Comet assay.ResultsAA reported an increased intake of heterocyclic amines and a decreased dietary intake of vitamins including vitamin D (p < 0.05) that correlated with differences in fecal microbiota composition but not fecal genotoxicity. Intake of dietary fiber, calcium, total fat and heterocyclic amines correlated with differences in microbiota composition. Total bacterial counts/g of stool and raw counts of Bacteroides were increased in AA. In contrast to a previous study, BMI was not associated with proportions of Bacteroides.ConclusionDietary habits of African Americans, including increased HCA intake and decreased vitamin D intake might at least partially contribute to CRC through modifications of gut microbiota composition that result in changes of the intestinal milieu.

Iron-overload induces oxidative DNA damage in the human colon carcinoma cell line HT29 clone 19A.

Dietary iron may contribute to colon cancer risk via production of reactive oxygen species (ROS). The aim of the study was to determine whether physiological ferric/ferrous iron induces oxidative DNA damage in human colon cells. Therefore, differentiated human colon tumour cells (HT29 clone 19A) were incubated with ferric-nitrilotriacetate (Fe-NTA) or with haemoglobin and DNA breaks and oxidised bases were determined by microgelelectrophoresis. The effects of Fe-NTA were measured with additional H(2)O(2) (75microM) and quercetin (25-100microM) treatment. Analytic detection of iron in cell cultures, treated with 250microM Fe-NTA for 15 min to 24h, showed that 48.02+/-5.14 to 68.31+/-2.11% were rapidly absorbed and then detectable in the cellular fraction. Fe-NTA (250-1000microM) induced DNA breaks and oxidised bases, which were enhanced by subsequent H(2)O(2) exposure. Simultaneous incubation of HT29 clone 19A cells with Fe-NTA and H(2)O(2) for 15 min, 37 degrees C did not change the effect of H(2)O(2) alone. The impact of Fe-NTA and H(2)O(2)-induced oxidative damage is reduced by the antioxidant quercetin (75-67% of H(2)O(2)-control). Haemoglobin was as effective as Fe-NTA in inducing DNA damage. From these results we can conclude that iron is taken up by human colon cells and participates in the induction of oxidative DNA damage. Thus, iron or its capacity to catalyse ROS-formation, is an important colon cancer risk factor. Inhibition of damage by quercetin reflects the potential of antioxidative compounds to influence this risk factor. Quantitative data on the genotoxic impact of ferrous iron (e.g. from red meat) relative to the concentrations of antioxidants (from plant foods) in the gut are now needed to determine the optimal balance of food intake that will reduce exposure to this type of colon cancer risk factor.

Butyrate is only one of several growth inhibitors produced during gut flora-mediated fermentation of dietary fibre sources

Dietary fibre sources are fermented by the gut flora to yield short-chain fatty acids (SCFA) together with degraded phytochemicals and plant nutrients. Butyrate, a major SCFA, is potentially chemoprotective by suppressing the growth of tumour cells and enhancing their differentiation. Conversely, it could lead to a positive selection pressure for transformed cells by inducing glutathione S-transferases (GST) and enhancing chemoresistance. Virtually nothing is known about how butyrates activities are affected by other fermentation products. To investigate such interactions, a variety of dietary fibre sources was fermented with human faecal slurries in vitro, analysed for SCFA, and corresponding SCFA mixtures were prepared. HT29 colon tumour cells were treated for 72 h with individual SCFA or complex samples. The growth of cells, GST activity, and chemoresistance towards 4-hydroxynonenal were determined. Fermentation products inhibited cell growth more than the corresponding SCFA mixtures, and the SCFA mixtures were more active than butyrate, probably due to phytoprotectants and to propionate, respectively, which also inhibit cell growth. Only butyrate induced GST, whereas chemoresistance was caused by selected SCFA mixtures, but not by all corresponding fermentation samples. In summary, fermentation supernatant fractions contain compounds that: (1) enhance the anti-proliferative properties of butyrate (propionate, phytochemical fraction); (2) do not alter its capacity to induce GST; (3) prevent chemoresistance in tumour cells. It can be concluded that fermented dietary fibre sources are more potent inhibitors of tumour cell growth than butyrate alone, and also contain ingredients which counteract the undesired positive selection pressures that higher concentrations of butyrate induce in tumour cells.

Assessment of DNA damage and its modulation by dietary and genetic factors in smokers using the Comet assay: a biomarker model

Abstract Methods are needed to assess exposure to genotoxins in humans and to improve understanding of dietary cancer prevention. The Comet assay was used to detect smoking-related exposures and dietary modulations in target tissues. Buccal scrapings, blood and faeces were collected from 38 healthy male volunteers (smokers and non-smokers) during a dietary intervention study with bread supplemented with prebiotics±antioxidants. GSTM1-genotype was determined with PCR. Buccal and peripheral lymphocytes were analysed for DNA damage using the Comet assay. Genotoxicity of faecal water (FW) was assayed in human colon HT29 clone 19A cells. ‘Tail intensity’ (TI) was used as a quantitative indicator of DNA damage in the Comet assay. Intervention with bread reduced DNA damage in lymphocytes of smokers (8.3±1.7% TI versus 10.2±4.1% TI, n=19), but not of non-smokers (8.6±2.8% TI versus 8.3±2.7% TI, n=15). Faecal water genotoxicity was reduced only in non-smokers (9.4±2.9% TI versus 18.9±13.1% TI, n=15) but not in smokers (15.5±10.7% TI versus 20.4±14.1% TI, n=13). The Comet assay was efficient in the detection of both smoking-related exposure (buccal cells) and efficacy of dietary intervention (faecal samples). Smokers and non-smokers profited differently from the intervention with prebiotic bread±antioxidants. Stratification of data by genotype enhanced specificity/sensitivity of the intervention effects and contributed important information on the role of susceptibility.

Initial in vitro toxicity testing of functional foods rich in catechins and anthocyanins in human cells

Functional foods need to be assessed for beneficial effects to support claims, but also for toxic effects. This report describes two examples of how complex food samples are initially characterized in human cells in vitro. Water extracts of green tea (GT) and black carrots (BC) were analyzed for key ingredients (catechins and anthocyanidins, respectively). Extracts, reconstituted mixtures of the major ingredients or individual compounds [(-)-epigallocatechin gallate or cyanidin, respectively] were evaluated in parallel using human colon cells (HT29 clone 19A). End points of cytotoxicity included determination of membrane integrity, proliferation inhibition, and genetic damage. Cells were pretreated with plant compounds at sub-toxic concentrations, and their resistance to toxicity of H2O2 was evaluated as a parameter of protection. The extracts reduced cell viability (BC) and cell growth (BC, GT) and caused DNA damage (BC, GT). They were more toxic than their key ingredients. Neither GT-samples nor BC protected against H2O2-induced DNA damage, whereas cyanidin did. In vitro analysis of extracts from functional foods firstly aims at defining the sub-toxic concentrations at which protective activities are then further characterized. It also allows comparing responses of complex samples and individual compounds, which is important since effects from protective food ingredients can be masked by accompanying toxic components.

The biological importance of nickel in the food chain

The ultra trace element nickel (Ni) is both essential and toxic for animals and humans. A Ni-poor nutrition of <0.1 mg/kg dry matter led to Ni deficiency symptoms. Ni is a component of the urease and it is also essential for several species of bacteria which occur in the rumen of ruminants. Ni deficiency symptoms, however, have not yet been found in animals and humans since the Ni offer exceeds the Ni requirement. On the other hand, an external Ni exposure to nickel alloys induces Ni dermatitis in 8 to 14% of nickel-sensitive women and in >1% of men after the filling of the Ni depot in the body. Experiments with 4 animal species showed that Ni exposure leads to disturbances in the Mg and above all in the Zn metabolism. Ni excess induces Zn deficiency symptoms which are similar to parakeratosis in pigs. They correspond to the symptoms of nickel allergy in humans. Therefore, the Ni intake of humans, which leads to the gradual filling of the Ni pool in the body and which can then induce nickel dermatitis in Ni-sensitive women and men, is of particular importance. The Ni requirement of adults does not exceed 25 to 35 μg/day. The Ni balance of men and women was positive (+20%) and shows the Ni incorporation even in the case of a Ni consumption which exceeds by far the requirement.

Use of Comet-FISH in the study of DNA damage and repair : Review

The Comet-FISH technique is a useful tool to detect overall and region-specific DNA damage and repair in individual cells. It combines two well-established methods, the Comet assay (single cell gel electrophoresis) and the technique of fluorescence in situ hybridization (FISH). Whereas the Comet assay allows separating fragmented from non-fragmented DNA, FISH helps to detect specifically labelled DNA sequences of interest, including whole chromosomes. Thus the combination of both techniques has been applied in particular for detection of site-specific breaks in DNA regions which are relevant for development of different diseases. This paper reviews the relevant literature and presents three examples on how Comet-FISH was used for studying the induction of DNA damage by genotoxic compounds related to oxidative stress in colon cancer-relevant genes (TP53, APC, KRAS) of a colon adenoma cell line. The accumulated evidence on relative sensitivity of these genes in comparison to global damage allows a more definite conclusion on the possible contribution of the genotoxic factors during colorectal carcinogenesis. Telomere fragility was compared in different cell lines treated with cytostatic agents, and revealed new patterns of biological activities through the drugs and different sensitivities of the cell lines that were found to be associated with their tumour origin. A third example relates to measuring repair of specific gene regions using Comet-FISH, a method that can be developed to biomarker application. Taken together, available data suggests that Comet-FISH helps to get further insights into sensitivity of specific DNA regions and consequently in mechanisms of carcinogenesis. Although the nature of the measured Comet-FISH endpoint precludes us from stating basically that damage and repair are occurring within the specific gene, it is at least possible to evaluate whether the damage and repair are occurring within the vicinity of the gene of interest.

Fermentation products of inulin-type fructans reduce proliferation and induce apoptosis in human colon tumour cells of different stages of carcinogenesis.

Epidemiological evidence suggests that the intake of prebiotic dietary fibres, for example, inulin, protects against colorectal cancer. However, little is known about cellular responses to complex fermentation samples. Therefore, we prepared a fermentation supernatant fraction of inulin and studied biological properties in human colon cell lines, LT97 and HT29 (representing early and late stages of colon cancer). Inulin enriched with oligofructose (Synergy 1) was incubated under anaerobic conditions with faecal inocula and the supernatant fraction was characterised for content of SCFA and secondary bile acid deoxycholic acid (DCA). A Synergy fermentation supernatant fraction (SFS) and a synthetic fermentation mixture (SFM) mimicking the SFS in SCFA and DCA content were used in the concentration range of 1.25-20 % (v/v) for 24-72 h. The effects on cell growth were determined by quantifying DNA. Effects on apoptosis were analysed by measuring poly(ADP-ribose) polymerase (PARP) cleavage using Western blotting. Compared with the faecal blank, produced without the addition of inulin, the SFS resulted in an almost 2.5-fold increase of SCFA and 3.4-fold decrease of DCA. In comparison with HT29 cells, LT97 cells responded more sensitively to the growth-inhibitory activities. Additionally, a significant increase in PARP cleavage was observed in LT97 cells after incubation with the SFS, demonstrating induction of apoptosis. The present results indicate growth-inhibiting and apoptosis-inducing effects of fermentation supernatant fractions of inulin. Moreover, since early adenoma cells were found to be more sensitive, this may have important implications for chemoprevention when translated to the in vivo situation, because survival of early transformed cells could be reduced.

Influence of prebiotics and antioxidants in bread on the immune system, antioxidative status and antioxidative capacity in male smokers and non-smokers

Interest in functional foods is increasing. The aim of the present study was to investigate breads supplemented with functional components. One was bread supplemented with inulin, linseed and soya fibre (prebiotic bread). The other was a prebiotic antioxidant bread (pre-aox-bread), which additionally contained green tea powder, herbs and tomato paste. The effects of these two breads on immunological and antioxidative parameters were compared with control bread (placebo). Twenty smokers and eighteen non-smokers were enrolled in the randomised parallel study, which consisted of a control period and an intervention period, each lasting for 5 weeks. Daily intake of bread and nutrients did not differ between the intervention and the control period. Most of the twenty-three investigated immunological parameters measured in peripheral blood were unaffected. However, the percentage of CD19 increased after intervention with prebiotic bread, whereas intercellular adhesion molecule-1 (ICAM-1) and CD3+NK+ (P < 0.05) decreased in both intervention arms. The ferric reducing ability of plasma (FRAP) was increased after consumption of the pre-aox-bread for non-smokers (1256 v. 1147 micromol/l; P = 0.019) and remained unchanged for smokers consuming the pre-aox-bread. All analysed carotenoids (P <or= 0.001) in plasma were increased after the consumption of pre-aox-bread. The concentrations of uric acid and alpha-tocopherol rose after intervention with both breads. ICAM-1 as a marker of stress decreased after consuming the prebiotic bread. In conclusion, increased plasma concentrations of carotenoids and the responses observed with the FRAP assay after intervention with the pre-aox-bread indicate a unique response in terms of antioxidative potentials for this type of functional food.