The metabolism of alpha- and gamma-tocotrienol was investigated in HepG2 cells. Metabolites were identified by HPLC and gas chromatography/mass spectrometry. gamma-Tocotrienol was degraded to gamma-CEHC (carboxyethyl hydroxychroman), gamma-CMBHC (carboxymethylbutyl hydroxychroman), gamma-CMHenHC (carboxymethylhexenyl hydroxychroman), gamma-CDMOenHC (carboxydimethyloctenyl hydroxychroman) and gamma-CDMD(en)(2)HC (carboxydimethyldecadienyl hydroxychroman). alpha-Tocotrienol yielded alpha-CEHC, alpha-CMBHC, alpha-CMHenHC and alpha-CDMOenHC, whereas alpha-CDMD(en)(2)HC could not be detected. These findings demonstrate that the trienols are metabolized essentially like tocopherols, i.e., by omega-oxidation followed by beta-oxidation of the side chain. The failure to detect CMBHC with the original double bond in the side chain reveals that auxiliary enzymes are involved, as in the metabolism of unsaturated fatty acids. CMBHC were the most abundant metabolites obtained from the tocotrienols as well as from alpha-tocopherol. Quantitatively, the tocotrienols were degraded to a larger extent than their counterparts with saturated side chains. The pronounced quantitative differences in the metabolism between individual tocopherols as well as between tocotrienols and tocopherols in vitro suggest a corresponding lack of equivalence in vivo.
Some 80 years after its discovery, vitamin E has experienced a renaissance which is as surprising as it is trivial. Although vitamin E is essential for reproduction, in rats at least, and deficiency causes neurological disorders in humans, the main interest in the last decades has concentrated on its antioxidant functions. This focus has highly underestimated the biological importance of vitamin E, which by far exceeds the need for acting as a radical scavenger. Only recently has it become clear that vitamin E can regulate cellular signaling and gene expression. Out of the eight different tocols included in the term vitamin E, alpha-tocopherol often exerts specific functions, which is also reflected in its selective recognition by proteins such as the alpha-tocopherol transfer protein and alpha-tocopherol-associated proteins. Vitamin E forms other than alpha-tocopherol are very actively metabolised, which explains their low biopotency. In vivo, metabolism may also attenuate the novel functions of gamma-tocopherol and tocotrienols observed in vitro. On the other hand, metabolites derived from individual forms of vitamin E have been shown to exert effects by themselves. This article focuses on the metabolism and novel functions of vitamin E with special emphasis on differential biological activities of individual vitamin E forms.
Global gene expression profiles of livers from mice, fed diets differing in alpha-tocopherol content, were compared using DNA microarray technology. Three hundred and eighty nine genes were found to significantly differ in their expression level by a factor of 2 or higher between the high and the low alpha-tocopherol group. Functional clustering using the EASE software identified 121 genes involved in transport processes. Twenty-one thereof were involved in (synaptic) vesicular trafficking. Up-regulation of syntaxin 1C (Stx1c), vesicle-associated membrane protein 1 (Vamp1), N-ethylmaleimide-sensitive factor (Nsf) and syntaxin binding protein 1 (Stxbp1, Munc18-1) was verified by real time PCR. At a functional level, alpha-tocopherol increased the secretory response in RBL and PC12 cells. Although here detected in liver, the alpha-tocopherol-responsive pathways are also relevant to neurotransmission. A role of alpha-tocopherol in the vesicular transport might not only affect its own absorption and transport but also explain the neural dysfunctions observed in severe alpha-tocopherol deficiency.
Our findings suggest that alpha-TTP-deficiency in states of alpha-TOH supplementation unexpectedly promotes glucose tolerance in mice due to both increased insulin secretion and insulin action, suggesting differential roles of alpha-TTP and alpha-TOH in the pathogenesis of type 2 diabetes mellitus.
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