Deoxynivalenol and its metabolite deepoxy-deoxynivalenol: multi-parameter analysis for the evaluation of cytotoxicity and cellular effects

Springler, Alexandra; Hessenberger, Sabine; Reisinger, Nicole; Kern, Corinna; Nagl, Veronika; Schatzmayr, Gerd; Mayer, Eric

doi:10.1007/s12550-016-0260-z

Cited by 50 publications

(39 citation statements)

References 58 publications

(80 reference statements)

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“…At the concentrations used in this work, the oxidative parameters analyzed were not changed. Springler et al measured the oxidative status in intestinal cell cultures exposed to DON and did not find increased ROS, although they did observe altered mitochondrial morphology. Investigations demonstrating that the mitochondrial changes caused by DON can alter the cell oxidative status were carried out using doses higher than those of this work.…”

Section: Discussionmentioning

confidence: 97%

Chronic ingestion of deoxynivalenol‐contaminated diet dose‐dependently decreases the area of myenteric neurons and gliocytes of rats

Rissato

Rampazzo

Borges

et al. 2019

Neurogastroenterology Motil

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Background Deoxynivalenol (DON), a mycotoxin produced by Fusarium spp., is commonly found in cereals ingested by humans and animals. Its ingestion is correlated with hepatic, hematologic, renal, splenic, cardiac, gastrointestinal, and neural damages, according to dose, duration of exposure and species. In this work, the effects of the ingestion of DON‐contaminated diet at concentrations considered tolerable for human and animal intake were assessed. Methods Male Wistar rats aging 21 days were allotted to five groups that were given, for 42 days, diets contaminated with different concentrations of DON (0, 0.2, 0.75, 1.75, and 2 mg kg−1 of chow). Food ingestion, bodyweight, oxidative status and morphometric analyses of gliocytes, and neurons of jejunal myenteric ganglia were recorded. Key Results At these concentrations, there was no food rejection, decrease in bodyweight gain, changes in oxidative status, or loss of either neurons or gliocytes. However, DON decreased gliocyte area, general neuronal population, nitrergic, cholinergic and NADH‐diaphorase positive subpopulations and, as a result, ganglion area. Conclusions & Inferences It was concluded that, even in the absence of visible effect, DON exposure reduces cell body area of gliocytes and neurons of the myenteric plexus of the rat jejunum.

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Section: Discussionmentioning

confidence: 97%

Chronic ingestion of deoxynivalenol‐contaminated diet dose‐dependently decreases the area of myenteric neurons and gliocytes of rats

Rissato

Rampazzo

Borges

et al. 2019

Neurogastroenterology Motil

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“…In chickens and turkeys, DOM‐1 was metabolized as DOM‐3‐sulfate by oral ingestion (Schwartz‐Zimmermann et al., 2015). DOM‐1 did not activate the phosphorylation of the MAPK pathway in IPEC‐J2 cells, Caco‐2 cells, or jejunal explants, such as p38/MAPK, JNK/MAPK and ERK 1/2 /MAPK, and Sapk/JNK (Pierron, 2016; Springler et al., 2017). DOM‐1 retained the ability to fit into the A‐site of the ribosome peptidyl transferase, and only two hydrogen bonds were formed.…”

Section: Toxicity Of Don and Its Modified Formsmentioning

confidence: 99%

“…DOM‐1 showed no significant effects on the viability of RAW 264.7 cells, Jurkat T cells, RTgill‐W1, IPEC‐1, Caco‐2 cells, and IPEC‐J2. In addition, DOM‐1 hardly influenced membrane integrity, barrier function, cellular metabolism, intracellular ATP, caspase‐3, GSH/GSSG ratio, reactive oxygen species (Springler et al., 2017), mitochondrial activity, cytochrome c, and Bcl‐2 (Nasri, Bosch, Ten Voorde, & Fink‐Gremmels, 2006). The IC 50 of DOM‐1 was 55 times higher than that of DON in 3T3 fibroblasts (Eriksen, Pettersson, & Lundh, 2004).…”

Section: Toxicity Of Don and Its Modified Formsmentioning

confidence: 99%

Deoxynivalenol: Masked forms, fate during food processing, and potential biological remedies

Guo

Wang

et al. 2020

Comp Rev Food Sci Food Safe

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Deoxynivalenol (DON) has drawn global attention because of its prevalence and significant effects on human or animal health. Biological remedies for DON have been developed from preharvest to postharvest. Applying microbes, including bacteria, fungi (yeast and molds), and enzymes, results in inhibited synthesis, structural destruction, or adsorption of DON. DON can be degraded into masked forms by phase I metabolism or phase II metabolism. During food processing, DON content changes dynamically and is even transformed. Physical, chemical, thermal, or biological processes physically reduce DON content. Temperature, heating time, enzymes, food additives, microorganisms, food composition, contamination level, and other ingredients are key factors. Although DON content can be reduced during food processing, increases in other toxins, such as DON‐3‐β‐d‐glucoside and 3‐acetyl‐DON, can be potentially risky. The application of biodegradation methods in food processing bears research significance. Both microorganisms and enzymes can be potentially used. Novel techniques, such as RNA interference, omics technologies, or enzymes coupled with the genetic engineering method, can be introduced. This review systematically updates the understanding of masked forms of DON, biological degradation strategy, fate of DON during processing, and future trends for biodegradation. Challenges to the successful application of biological methods may include the stability and suitability of the detoxification agents, security of degradation products, and successful application for industrial production.

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“…The given concentrations were selected based on previously published studies (Malekinejad et al, 2007;Pinton et al, 2012;Springler et al, 2017). The proposed concentrations of DON (0, 2.5, 5 and 10 μM) were prepared by using Ham's F10 culture medium (Sigma-Aldrich, Germany).…”

Section: Mycotoxin Preparationmentioning

confidence: 99%

Deoxynivalenol reduces quality parameters and increases DNA damage in mice spermatozoa

et al. 2019

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This study was performed to investigate in vitro effects of deoxynivalenol (DON) on mice sperm quality parameters including viability, motility and DNA damages at various concentrations and exposure times. Mice spermatozoa were exposed to DON at 0, 2.5, 5 and 10 µM for 1, 3 and 6 hr, motility parameters were evaluated by computer‐assisted analysis and viability was examined by colorimetric metabolic activity assay and HOS test. DNA damage was examined by acridine orange staining, and sperm damages via lipid peroxidation pathway were determined by malondialdehyde (MDA) content measurement. DON affected sperm parameters in a concentration‐ and time‐dependent manner. In all test groups, the average path velocity and progressive motile spermatozoa were remarkably reduced. In comparison with the controls, after 1, 3 and 6 hr exposure to DON, viability of spermatozoa was reduced 25, 30 and 49% respectively. DON exposure at 10 µM for 6 hr resulted in 15% DNA damage and 2.5‐fold more MDA generation, when compared with nonexposed spermatozoa. Our data suggest that DON causes sperm quality parameters decline in concentration‐ and time‐dependent fashion, which attribute to the reduction in sperm metabolic activity and membrane integrity and equally to increase in lipid peroxidation rate and DNA damage.

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Deoxynivalenol and its metabolite deepoxy-deoxynivalenol: multi-parameter analysis for the evaluation of cytotoxicity and cellular effects

Cited by 50 publications

References 58 publications

Chronic ingestion of deoxynivalenol‐contaminated diet dose‐dependently decreases the area of myenteric neurons and gliocytes of rats

Chronic ingestion of deoxynivalenol‐contaminated diet dose‐dependently decreases the area of myenteric neurons and gliocytes of rats

Deoxynivalenol: Masked forms, fate during food processing, and potential biological remedies

Deoxynivalenol reduces quality parameters and increases DNA damage in mice spermatozoa

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