Abstract
There is interest in supplementing animals and humans with selenium (Se) above Se-adequate levels, but the only good biomarker for toxicity is tissue Se. We targeted liver because turkeys fed 5 μg Se/g have hepatic Se concentrations 6-fold above Se-adequate (0.4 μg Se/g) levels without effects on growth or health. Our objectives were (i) to identify transcript biomarkers for high Se status, which in turn would (ii) suggest proteins and pathways used by animals to adapt to high Se. Turkey poults were fed 0, 0.025, 0.4, 0.75 and 1.0 μg Se/g diet in experiment 1, and fed 0.4, 2.0 and 5.0 μg Se/g in experiment 2, as selenite, and the full liver transcriptome determined by RNA-Seq. The major effect of Se-deficiency was to down-regulate expression of a subset of selenoprotein transcripts, with little significant effect on general transcript expression. In response to high Se intake (2 and 5 μg Se/g) relative to Se-adequate turkeys, there were only a limited number of significant differentially expressed transcripts, all with only relatively small fold-changes. No transcript showed a consistent pattern of altered expression in response to high Se intakes across the 1, 2 and 5 μg Se/g treatments, and there were no associated metabolic pathways and biological functions that were significant and consistently found with high Se supplementation. Gene set enrichment analysis also found no gene sets that were consistently altered by high-Se and supernutritional-Se. A comparison of differentially expressed transcript sets with high Se transcript sets identified in mice provided high Se (~3 μg Se/g) also failed to identify common differentially expressed transcript sets between these two species. Collectively, this study indicates that turkeys do not alter gene expression in the liver as a homeostatic mechanism to adapt to high Se.
Highlights
Selenium (Se) was first identified as a toxic element for livestock in the 1930s [1], and reported to be carcinogenic for rats [2], lumping Se as a poison with other elements like arsenic
This study indicates that turkeys do not alter gene expression in the liver as a homeostatic mechanism to adapt to high Se
The response of the liver transcriptome in turkey poults was studied in two experiments that fed graded levels of inorganic Se in diets supplemented with vitamin E at 12.5X the NRC requirement [32] so that direct effects of altered Se status could be studied without downstream secondary effects arising from physiological effects of Se deficiency or toxicity in combination with marginal vitamin E status
Summary
Selenium (Se) was first identified as a toxic element for livestock in the 1930s [1], and reported to be carcinogenic for rats [2], lumping Se as a poison with other elements like arsenic. In 1957, Se was found to be an essential nutrient for rats [3] and chickens [4], and soon after was shown to prevent a cardiomyopathy in humans called Keshan disease [5]. In 1973, Se was identified as an essential cofactor for glutathione peroxidase (GPX), establishing a biochemical role for Se as a required essential trace element [6]. Tissue Se concentrations, signs of Se-specific disease, and selenoenzyme activities can be good biomarkers of Se status and Se deficiency
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