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Foodborne cereulide causes beta-cell dysfunction and apoptosis.

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Published

Peer reviewed scientific article

English

DOI : https://doi.org/10.1371/journal.pone.0104866 [2]

Authors

Vangoitsenhoven, Roman [3]; Rondas, Dieter [4]; Inne Crèvecoeur [5]; D'Hertog, Wannes [6]; Baatsen, Pieter [7]; Masini, Matilde [8]; Mirjana Andjelkovic [9]; Joris Van Loco [10]; Matthys, Christophe [11]; Mathieu, Chantal [12]; Overbergh, Lut [13]; Van der Schueren, Bart [14]

Keywords

  1. Animals [15]
  2. Apoptosis [16]
  3. Cell Line [17]
  4. Cercopithecus aethiops [18]
  5. COS Cells [19]
  6. Depsipeptides [20]
  7. Food Microbiology [21]
  8. Glucose [22]
  9. Hep G2 Cells [23]
  10. Humans [24]
  11. Insulin [25]
  12. Insulin-Secreting Cells [26]
  13. Islets of Langerhans [27]
  14. mice [28]
  15. Mice, Inbred C57BL [29]
  16. Mitochondria [30]
  17. rats [31]

Abstract:

AIMS/HYPOTHESIS: To study the effects of cereulide, a food toxin often found at low concentrations in take-away meals, on beta-cell survival and function.METHODS: Cell death was quantified by Hoechst/Propidium Iodide in mouse (MIN6) and rat (INS-1E) beta-cell lines, whole mouse islets and control cell lines (HepG2 and COS-1). Beta-cell function was studied by glucose-stimulated insulin secretion (GSIS). Mechanisms of toxicity were evaluated in MIN6 cells by mRNA profiling, electron microscopy and mitochondrial function tests.RESULTS: 24 h exposure to 5 ng/ml cereulide rendered almost all MI…
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Abstract

AIMS/HYPOTHESIS: To study the effects of cereulide, a food toxin often found at low concentrations in take-away meals, on beta-cell survival and function.

METHODS: Cell death was quantified by Hoechst/Propidium Iodide in mouse (MIN6) and rat (INS-1E) beta-cell lines, whole mouse islets and control cell lines (HepG2 and COS-1). Beta-cell function was studied by glucose-stimulated insulin secretion (GSIS). Mechanisms of toxicity were evaluated in MIN6 cells by mRNA profiling, electron microscopy and mitochondrial function tests.

RESULTS: 24 h exposure to 5 ng/ml cereulide rendered almost all MIN6, INS-1E and pancreatic islets apoptotic, whereas cell death did not increase in the control cell lines. In MIN6 cells and murine islets, GSIS capacity was lost following 24 h exposure to 0.5 ng/ml cereulide (P<0.05). Cereulide exposure induced markers of mitochondrial stress including Puma (p53 up-regulated modulator of apoptosis, P<0.05) and general pro-apoptotic signals as Chop (CCAAT/-enhancer-binding protein homologous protein). Mitochondria appeared swollen upon transmission electron microscopy, basal respiration rate was reduced by 52% (P<0.05) and reactive oxygen species increased by more than twofold (P<0.05) following 24 h exposure to 0.25 and 0.50 ng/ml cereulide, respectively.

CONCLUSIONS/INTERPRETATION: Cereulide causes apoptotic beta-cell death at low concentrations and impairs beta-cell function at even lower concentrations, with mitochondrial dysfunction underlying these defects. Thus, exposure to cereulide even at concentrations too low to cause systemic effects appears deleterious to the beta-cell.

Associated health topics:


Source URL:https://sciensano.be/en/biblio/foodborne-cereulide-causes-beta-cell-dysfunction-and-apoptosis

Links
[1] https://sciensano.be/sites/default/files/pone.0104866.pdf [2] https://doi.org/10.1371/journal.pone.0104866 [3] https://sciensano.be/en/biblio?f%5Bauthor%5D=46854&amp;f%5Bsearch%5D=Vangoitsenhoven%2C%20Roman [4] https://sciensano.be/en/biblio?f%5Bauthor%5D=46857&amp;f%5Bsearch%5D=Rondas%2C%20Dieter [5] https://sciensano.be/en/people/inne-crevecoeur/biblio [6] https://sciensano.be/en/biblio?f%5Bauthor%5D=46863&amp;f%5Bsearch%5D=D%27Hertog%2C%20Wannes [7] https://sciensano.be/en/biblio?f%5Bauthor%5D=46866&amp;f%5Bsearch%5D=Baatsen%2C%20Pieter [8] https://sciensano.be/en/biblio?f%5Bauthor%5D=46869&amp;f%5Bsearch%5D=Masini%2C%20Matilde [9] https://sciensano.be/en/people/mirjana-andjelkovic/biblio [10] https://sciensano.be/en/people/joris-van-loco/biblio [11] https://sciensano.be/en/biblio?f%5Bauthor%5D=46872&amp;f%5Bsearch%5D=Matthys%2C%20Christophe [12] https://sciensano.be/en/biblio?f%5Bauthor%5D=46875&amp;f%5Bsearch%5D=Mathieu%2C%20Chantal [13] https://sciensano.be/en/biblio?f%5Bauthor%5D=46878&amp;f%5Bsearch%5D=Overbergh%2C%20Lut [14] https://sciensano.be/en/biblio?f%5Bauthor%5D=46881&amp;f%5Bsearch%5D=Van%20der%20Schueren%2C%20Bart [15] https://sciensano.be/en/biblio?f%5Bkeyword%5D=423&amp;f%5Bsearch%5D=Animals [16] https://sciensano.be/en/biblio?f%5Bkeyword%5D=24648&amp;f%5Bsearch%5D=Apoptosis [17] https://sciensano.be/en/biblio?f%5Bkeyword%5D=462&amp;f%5Bsearch%5D=Cell%20Line [18] https://sciensano.be/en/biblio?f%5Bkeyword%5D=24318&amp;f%5Bsearch%5D=Cercopithecus%20aethiops [19] https://sciensano.be/en/biblio?f%5Bkeyword%5D=31137&amp;f%5Bsearch%5D=COS%20Cells [20] https://sciensano.be/en/biblio?f%5Bkeyword%5D=19737&amp;f%5Bsearch%5D=Depsipeptides [21] https://sciensano.be/en/biblio?f%5Bkeyword%5D=2178&amp;f%5Bsearch%5D=Food%20Microbiology [22] https://sciensano.be/en/biblio?f%5Bkeyword%5D=20082&amp;f%5Bsearch%5D=Glucose [23] https://sciensano.be/en/biblio?f%5Bkeyword%5D=32328&amp;f%5Bsearch%5D=Hep%20G2%20Cells [24] https://sciensano.be/en/biblio?f%5Bkeyword%5D=648&amp;f%5Bsearch%5D=Humans [25] https://sciensano.be/en/biblio?f%5Bkeyword%5D=18525&amp;f%5Bsearch%5D=Insulin [26] https://sciensano.be/en/biblio?f%5Bkeyword%5D=30762&amp;f%5Bsearch%5D=Insulin-Secreting%20Cells [27] https://sciensano.be/en/biblio?f%5Bkeyword%5D=32331&amp;f%5Bsearch%5D=Islets%20of%20Langerhans [28] https://sciensano.be/en/biblio?f%5Bkeyword%5D=2454&amp;f%5Bsearch%5D=mice [29] https://sciensano.be/en/biblio?f%5Bkeyword%5D=28188&amp;f%5Bsearch%5D=Mice%2C%20Inbred%20C57BL [30] https://sciensano.be/en/biblio?f%5Bkeyword%5D=32334&amp;f%5Bsearch%5D=Mitochondria [31] https://sciensano.be/en/biblio?f%5Bkeyword%5D=5418&amp;f%5Bsearch%5D=rats