Vitamin E is composed of eight naturally occurring isoforms, namely, four tocopherols (α-, β-, δ-, and γ) and four tocotrienols (α-, β-, δ-, and γ), which differ by the number and position of the methyl groups on the chromanol ring and the level of saturation in their side chains (1). The tocopherols have a saturated phytyl tail, while the tocotrienols have an unsaturated isoprenoid tail (2). In addition to its antioxidant properties, vitamin E also exerts non-antioxidant functions, such as modulating DNA repair systems, gene expression and signal transduction (3).

Most commercially available vitamin E supplements contain only α-tocopherol (α-TF). This isoform is commonly used because of its high bioavailability; compared to other isoforms, it is easily recognized by the hepatic α-TF transfer protein (TTP), and it is enriched in human plasma and tissues (4). However, α-TF alone may not be the best formulation for vitamin E supplementation, because the intake of vitamin E should reflect its natural composition, which consists of all isomers (5). Emerging evidence has shown that tocotrienol has higher antioxidant activity (4) and more potent antihypercholesterolemic (6), anti-inflammatory (7), antithrombotic (8), anticancer (9 , 10 , 11), hepatoprotective (12) and neuroprotective (13) properties than tocopherol.

A previous study by Chin et al. (14) reported that vitamin E responses were age-dependent; tocotrienol-rich fraction (TRF) supplementation resulted in a greater reduction in total DNA damage in older adults (>50 y) than in younger adults (35-49 y). In addition, improved serum lipid profiles and levels of vitamins E and C, as well as decreased levels of protein and lipid damage, were observed in older adults supplemented with TRF (5). Furthermore, Eng et al. (15) found that changes in protein expression with TRF supplementation were more profound in older individuals (49-51 y) than in younger individuals (34-36 y). According to Marino et al. (16), nutrition could influence the health of males and females differently due to multifactorial inputs, including gene repertoires, sex steroid hormones, ontogenetic developments, environmental factors and differences in the bioavailability, metabolism, distribution, and elimination of nutrients. In addition to the uncertainty surrounding the sex-specific responses to supplementation, it is still unclear whether the previously observed effects were entirely due to tocotrienol, because TRF contains traces of tocopherol. Therefore, the aim of this study was to compare the effects of α-TF with TRF supplementation in male and female subjects aged 50-55 years.

In the elderly, the intake of essential macro- and micronutrients from the diet is usually inadequate. The deficiency of essential nutrients in aging is related to the global impairment of immune functions, metabolic harmony and antioxidant defense (18). With increasing age, the production of reactive oxygen species (ROS) is also increased due to an imbalance between antioxidant defense and ROS production. The resulting oxidative stress damages biomolecules such as DNA, protein and lipids, which eventually contributes to age-related diseases (19). Thus, supplementation with micronutrients with antioxidant properties, such as vitamin E, could prevent oxidative stress and molecular injury in aging.

The effects of α-TF and TRF on healthy older adults were compared in this study, and our results showed that each vitamin modulated the expression of different genes and regulated different pathways. Although the TRF supplements used in this study also contained α-tocopherol, the responses were different from the responses to α-TF supplementation alone. In the male subjects, α-TF supplementation for 3 months significantly stimulated the defense response pathway (p <0.007). Although this pathway was stimulated, the expression of most related genes (FC>1.5) decreased. The expression of the CD3 ε , or CD3-epsilon, gene (Entrez ID: NM_000733) (http://www.ncbi.nlm.nih.gov/gene/) was found to decrease with the highest fold change (1.6-fold). The CD complex plays an important role in coupling antigen recognition to several intracellular signal transduction pathways, such as T cell receptor (TCR) signal transduction (20). According to Li et al. (21), increased CD3 ε expression is related to the severity of aplastic anemia, which is an autoimmune disease. The results of this study suggest that α-TF induces a cellular defense response against pathogenic conditions by decreasing the expression of CD3 ε , which plays a role in autoimmune diseases. In addition, α-TF exerts an antiproliferative effect by upregulating the response to cAMP (11) and downregulating smooth muscle cell proliferation (22). The role of this vitamin as an antioxidant is also established, as the oxidative stress pathway was upregulated (23). The most significant pathway modulated after 6 months of α-TF supplementation was the mitosis pathway (p <0.008), which plays a crucial role in the cell cycle (24). Upregulated mitosis shows that α-TF promotes cell cycle progression and cell division. The expression of the gene SNX9 , or sorting nexin 9 (Entrez ID: NM_016224), was found to increase with the highest fold change (2.1-fold) in this pathway. According to Ma and Chircop (25), the SNX9 protein is essential for the progression and completion of mitosis, and the depletion of this protein induces multinucleation (an indication of cytokinesis failure) and the accumulation of cytokinetic cells. In addition, α-TF may have anti-inflammatory effects, as supplementation was found to downregulate the cell adhesion and cell response to bacterium pathways and inhibit proliferation by decreasing the activation of the MAPK activity pathway (26) in healthy male subjects.

In female subjects, the most significant pathway modulated by α-TF after 3 months of supplementation was the toxin metabolic process pathway (p <0.008). The upregulation of this pathway shows that α-TF may promote detoxification by eliminating various types of toxins, such as mutagens, carcinogens, drugs, excessive hormones and chemicals (27), from the body after as few as 3 months of supplementation. At this time point, α-TF was also found to upregulate xenobiotic metabolism, which is also related to the detoxification mechanism. Although both pathways were upregulated, the expression of most of the genes involved in these pathways was found to decrease. The expression of the CYP1A1 , or cytochrome P450 family 1 subfamily A member 1, gene (Entrez ID: NM_000499) was found to decrease with the highest fold change (1.5-fold). This gene encodes the P450-1A1 (CYP1A1) enzyme, which has aryl hydrocarbon hydroxylase activity (28). This enzyme converts polycyclic aromatic hydrocarbons (PAHs) to aryl epoxide carcinogens (29) and participates in estrogen metabolism by catalyzing the 2-hydroxylation of estradiol, which results in free radical and DNA adduct production (30). The decreased expression of this gene may inhibit the production of ROS that lead to cancer development. After 6 months of supplementation, α-TF significantly downregulated the signal transduction pathway (p <0.007). Signal transduction (also known as cell signaling) is a process of (chemical or physical) signal transmission through a cell that results in a response that may alter cell metabolism or gene expression (31). In this pathway, the expression of the TP53 , or tumor protein 53, gene (Entrez ID: NM_000546) was downregulated by 1.5-fold. This gene encodes a tumor suppressor protein that has a DNA binding site and transcriptional activation and oligomerization domains that respond to diverse cellular stresses to regulate targeted genes by inducing apoptosis, cell cycle arrest, DNA repair, senescence, or metabolic changes. Ishak et al. (32) reported that the increased expression of TP53 was detected in 50% of gallbladder carcinomas. According to Barabutis et al. (33), p53, which functions as a tumor suppressor, promotes apoptosis, cell cycle arrest and senescence under stress conditions. In this study, the decreased expression of the TP53 gene may be related to a decreased stress response with α-TF supplementation, leading to a downregulated signaling cascade as well as a decreased response to LPS, IL-1 and chemotaxis. α-TF may also exert anti-inflammatory effects by downregulating the cell adhesion (34) and cellular responses to iIL-1 pathways in healthy female subjects.

The G protein-coupled receptor signaling pathway was upregulated after 3 months of TRF supplementation in male subjects (0.007). G protein-coupled receptors (GPCRs) are located at the cell surface to convert endogenous signals or stimuli into a series of cellular responses (35). Although this pathway was upregulated by supplementation, most of the significant genes (FC>1.5) involved in this pathway were found to be downregulated, especially the GPR110 , or the adhesion G protein-coupled receptor F1, gene (Entrez ID: NM_025048), which was downregulated with the highest fold-change (2.4-fold). GPR110 is an orphan GPCR that has been identified as an oncogene overexpressed in some lung and prostate cancers and is used as a disease marker and therapeutic target for both types of tumors (36). Short-term supplementation with TRF may also promote the cell cycle by upregulating the cell division pathway and delay aging by downregulating the aging pathway. The most significant pathway upregulated after 6 months of TRF supplementation was the multicellular organismal development pathway (p =0.006). The CTNDD2 , or delta 2 catenin, gene (Entrez ID: NM_001332) was upregulated with the highest fold change (1.9-fold). This gene encodes a δ-catenin and is involved in the regulation of dendrite function and neuronal migration in the mature cortex (37). Intragenic CTNND2 deletion is found in patients with isolated intellectual disability (38). Based on these results, TRF has been suggested to have a neuroprotective effect in male subjects by downregulating the ERK1/2 cascade (13). TRF also exerts anti-inflammatory effects by decreasing cell adhesion (39) and suppressing integrin-mediated signaling, phosphatidylinositol-mediated signaling and cell-cell signaling pathways in male subjects.

In the female subjects, the biological process most significantly modulated after 3 months of TRF supplementation was the activation of protein kinase pathway (p <0.008). Protein kinase activity is modified by other proteins via phosphorylation, which results in the alteration of protein function (40). Though this process was stimulated by TRF supplementation, the expression of all the significant genes (FC>1.5) involved was decreased. The expression of the epidermal growth factor (EGF) gene was found to decrease with the highest fold change (2.2-fold) after supplementation. Decreased EGF expression is beneficial for the prevention of breast cancer because EGF is a potent mitogen for normal and neoplastic mammary epithelial cells (12). Indeed, McIntyre et al. (41) reported that tocotrienols specifically inhibit EGF-dependent mitogenesis in preneoplastic and neoplastic mammary epithelial cells. Like α-TF supplementation, TRF supplementation for 6 months downregulated the signal transduction pathway significantly (p <0.006). Among the genes in this pathway, TRF downregulated the LTB4R2 , or leukotriene B4 receptor 2, gene (Entrez ID: NM_001164692) with the highest fold change (2.4-fold). LTB4 is reported to be a potent proinflammatory lipid mediator that is overproduced in the pathogenesis of several inflammatory diseases (42), such as rheumatoid arthritis, bronchial asthma, ischemic renal failure, psoriasis and inflammatory bowel diseases (43). Studies have shown that LTB4 and its receptors critically regulate tumor progression by promoting cell proliferation, migration, survival and metastasis (44 , 45). Kim et al. (46) reported that the expression of the LTB4R2 gene (also known as BLT2) was upregulated in MCF-7 (a human breast cancer cell line)/DOX (doxorubicin) cells, whereas cotreatment with a BLT2 inhibitor markedly reduced tumor growth in an in vivo MCF-7/DOX model. TRF also exerts antiapoptotic effects by downregulating the apoptotic process pathway (47); furthermore, it shows neuroprotective properties by decreasing the ERK1/2 cascades (15 , 16) and anti-inflammatory and anticancer properties by downregulating the I-kappa B kinase-NF-kappa B signaling (48) and cell adhesion pathways (39) in healthy female subjects.

Overall, supplementation with either α-TF or TRF modulated the immune system, response to drug, cell adhesion and signal transduction pathways. de Magalhaes et al. (49) reported that age-related gene changes most notably involve an overexpression of immune response genes. Theriault et al. (39) reported that the anti-inflammatory and cardioprotective effects of tocotrienols are mediated through the ability of tocotrienols to downregulate the expression of adhesion molecules. For example, α-TF has been reported to prevent inflammation and atherosclerosis by reducing monocyte cell adhesion activity (50). Zingg (3) reported that vitamin E specifically modulates signal transduction in order to scavenge free radicals by directly interacting with signal transduction enzymes or by reducing ROS- and reactive nitrogen species (RNS)-induced damage to enzymes. Furthermore, Khanna et al. (51) showed that the neuroprotective effect of α-tocotrienol did not result from its antioxidant activity but from the suppression of specific signal transduction mediators. In this study, the ability of both types of vitamin E to suppress the signal transduction pathway may have led to the downregulation of most biological processes, especially in female subjects after 6 months of supplementation. Although the distribution of males and females in each supplementation group was similar, the study was limited because the number of females was greater than the number of males. Thus, further research encompassing a larger sample size with an equal distribution of males and females is necessary to confirm the sex-specific effects of α-TF and TRF supplementation observed in this study.

Both α-TF and TRF supplementation had similar effects on the immune system, drug response, cell adhesion and signal transduction pathways. However, TRF supplementation showed a more pronounced effect than α-TF in modulating the expression of genes in signaling pathways. The antioxidative and anti-inflammatory properties of TRF observed in female subjects may be attributed to the downregulation of the apoptotic pathway, ERK1/2 cascades and NF-kB pathway after 6 months of supplementation.

Abdul Ghani SM conducted the study, analysis and interpretation of data in addition to drafting the manuscript. Goon JA contributed to the study design and content of the manuscript. Nor Azman NHE and Zakaria SNA were involved in the subject screening, assessment of the physical activity questionnaire and interpretation of the data. Hamid Z contributed to supplying the placebo, α-TF and TRF supplementation capsules. Wan Ngah WZ was instrumental in the study's inception, design and approval and also provided a critical analysis of the data interpretation and manuscript review. The final manuscript has been read and approved by all authors.