Novel Soybean Oils Differing in Fat

Novel Soybean Oils Differing in Fatty Acid Composition Alter Immune Functions of Moderately Hypercholesterolemic Older Adults1,2,3
Abstract
Linoleic acid (LA) and α-linolenic acid (ALA) are essential fatty acids that play an important role in modulation of T cell proliferation. The effects of consuming novel soybean oils varying in LA:ALA ratios on T cell proliferation and inflammatory responses were assessed in older adults. Eighteen participants (>50 y old) with elevated cholesterol concentrations (3.37–4.14 mmol/L LDL cholesterol) consumed 5 experimental diets in random order for periods of 35 d. Each diet contained 30% of energy as fat, two-thirds of which was high-oleic acid soybean oil (HiOleic-SO), soybean oil (SO), low-SFA soybean oil (LoSFA-SO), hydrogenated soybean oil (Hydrog-SO), or low-ALA soybean oil (LoALA-SO), resulting in LA:ALA ratios of 2.98, 8.70, 9.69, 15.2, and 18.3, respectively. Participants had higher proliferative responses to phytohemagglutinin (PHA) compared with baseline following consumption of SO (26%; P < 0.05), LoSFA-SO (22%; P < 0.05), or HiOleic-SO (24%; P < 0.05) diets. Proliferative response was similar to the baseline after participants consumed diets with an LA:ALA ratio >10 (Hydrog-SO and LoALA-SO). Post-diet intervention, LA:ALA ratios correlated with proliferative responses to PHA (r = −0.87; P = 0.05). An optimal proliferative response was observed at an LA:ALA ratio of 8.70, with an inverse correlation between proliferative response and LA:ALA ratios >8.70. These effects were independent of changes in the production of PGE2, inflammatory cytokines, or cytokines involved in growth of lymphocytes. These data suggest that the LA:ALA ratio modulates the proliferative ability of T lymphocytes, which may be due to subtle changes in fatty acid composition of the phospholipids in immune cells.
Introduction
In the United States, the dietary (n-6):(n-3) fatty acid ratio is estimated to be ∼10:1, with an (n-3) fatty acid intake of ~1.6 g/d (0.7% of energy) (1). Some investigators have suggested an optimal (n-6):(n-3) fatty acid ratio of 6:1 (2). Higher ratios of (n-6):(n-3) fatty acid were associated with adverse effects on bone mineral density (3) and risk of prostate cancer (4). However, the FAO recently reported that there is no rationale for a specific recommendation for the (n-6):(n-3) fatty acid ratio if the (n-6) fatty acid intake is 2.5–9% energy and the (n-3) fatty acid intake is 0.5–2% energy (5). Likewise, the 2010 Dietary Guidelines for Americans (6) concluded that there are insufficient data to justify a specific recommendation for a dietary (n-6):(n-3) fatty acid ratio. For cardiovascular health, evidence suggests that both linoleic acid [LA7; 18:2(n-6)] and α-linolenic acid [ALA; 18:3(n-3)] have a role in reducing the risk of coronary heart disease (7, 8) and that the absolute amount consumed (of these essential fatty acids) should be emphasized rather than the ratio of (n-6):(n-3) fatty acids (2).
Inflammatory and T cell-mediated responses are dysregulated in older adults (9). In older adults with hypercholesterolemia, modulation of inflammatory and immune responses may be of more importance, because hypercholesterolemia has been associated with higher risk of infection in animal models (10, 11). The types and amounts of dietary fatty acids can modulate inflammation and T cell-mediated immune response; however, the reported results have not been always consistent. A diet high in ALA [ALA, 6.5% of energy and an (n-6):(n-3) fatty acid ratio of 2:1] decreased the production of the proinflammatory cytokines IL-6, IL-1β, and TNF -α by peripheral blood mononuclear cells (PBMC) in hypercholesterolemic participants compared with a diet high in LA [LA, 12.6% of energy and an (n-6):(n-3) fatty acid ratio of 4:1] or the average American diet [LA, 7.7% and ALA, 0.8% of energy and an (n-6):(n-3) fatty acid ratio of 10:1] (12). A diet containing flaxseed oil, which is high in ALA, suppressed the proliferation of PBMC and the delayed type hypersensitivity (DTH) response in healthy adults (13). Therefore, a high intake of ALA might have an inhibitory effect on inflammatory and T cell-mediated responses. However, the high ALA diets used in the above studies are impractical, because the amount of ALA or oils used in the study are higher than the average intake of the U.S. population. In a placebo-controlled, double-blind study that involved participants 25–72 y old, supplementation of 4.5 or 9.5 g/d of ALA or 0.77 or 1.7 g/d EPA + DHA for 6 mo did not alter immune functions as determined by the proliferative response of PBMC and the in vivo DTH response (14). Furthermore, results from an observational study by Merchant et al. (15) reported that participants consuming higher levels of ALA had a lower risk of pneumonia.
Newer plant breeding techniques have made it possible to alter the fatty acid composition of vegetable oils. In this study, we used selectively bred and genetica