High α-linolenic acid and fish oil ingestion promotes ovulation to the same extent in rats

Prostaglandins (PG) have a regulatory influence on ovulation. α-Linolenic acid (ALA) vs eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) differently influence PG biosynthesis. Whereas high EPA/DHA reduces PGE₂, enhancing ovulation, we hypothesized that ALA would not affect ovulation. Our objective was to determine the effect of low and high ALA intake vs EPA/DHA on ovarian phospholipids, ovulation, and PG synthesis in rats. Following 27 days on diet and ovulation induction, ovaries were isolated and analyzed in 22 pups per diet. Ovarian phospholipid (n-3) polyunsaturated fatty acid (PUFA) incorporation increased with EPA/DHA ingestion. With significant ovarian (n-3) PUFA or EPA (P < .05) enrichment in the high–n-3 PUFA diets, ova release increased. Although high ALA did not enrich total (n-3), it increased ova release and tissue EPA over low ALA or control. Dietary EPA/DHA more effectively reduced ovarian arachidonic acid levels than dietary ALA. Dietary ALA increased PGF and very high intake reduced PGE, whereas EPA/DHA did not alter PGE or PGF. Enhanced ova release with high (n-3) PUFA intake may be induced via multiple mechanisms including reduced ovarian arachidonic acid. Significant ovarian retention of EPA and DHA enhanced ovulation with unchanged total PGE and PGF. Lack of change in PGE may have resulted from reduced PGE₂ combined with increased PGE₃. When EPA alone was elevated, PGE was reduced, whereas PGF was increased. Results indicate that very high ALA intake enhances ovulation similar to very high EPA/DHA ingestion, an effect potentially mediated via similar patterns of PGF₂α and PGE₂ synthesis.     

Race differences in the relation of vitamins A,C, E,and β-carotene to metabolic and inflammatory biomarkers

Using archival data, we conducted a secondary analysis to examine race differences in the relation of serum vitamins A, C, E and β-carotene to insulin resistance (IR), fasting insulin and glucose, high sensitivity C-reactive protein (hs-CRP), and leukocyte count in 176 non-smoking, healthy, white, and African American (AA) adults aged 18 to 65 years (48% women, 33% AA). We hypothesized that micronutrient concentrations would be associated with early risk markers of cardiometabolic diseases in a race-dependent manner. Fasting blood samples were analyzed for micronutrients, insulin, glucose, hs-CRP, and leukocyte count. Insulin resistance was estimated using the homeostatic model assessment. After adjusting for age, body mass index, gender, educational level, use of vitamin supplements, alcohol intake, leisure time physical activity, menopausal status, and total cholesterol, we observed that β-carotene was significantly associated with insulin resistance and fasting insulin in a race-dependent manner. Among AA, lower β-carotene levels were associated with higher estimates of insulin resistance and fasting insulin; whereas, these same associations were not significant for whites. Race also significantly moderated the relation of vitamin C to leukocyte count, with lower vitamin C being associated with higher leukocyte count only in AA but not whites. For all subjects, lower β-carotene was associated with higher hs-CRP. In AA, but not whites, lower levels of β-carotene and vitamin C were significantly associated with early risk markers implicated in cardiometabolic conditions and cancer. Whether or not lower levels of micronutrients contribute uniquely to racial health disparities is a worthwhile aim for future research.     

α-Lipoic acid ameliorated oxidative stress induced by perilla oil,but the combination of these dietary factors was ineffective to cause marked deceases in serum lipid levels in rats

Dietary perilla oil rich in α-linolenic acid and α-lipoic acid lowers the serum lipid level through changes in hepatic fatty acid metabolism. We therefore hypothesized that the combination of these dietary factors may ameliorate lipid metabolism more than the factors individually. Moreover, α-lipoic acid exerts strong anti-oxidative activity. Hence, we also hypothesized that α-lipoic acid may attenuate perilla oil-mediated oxidative stress. We therefore studied the combined effects of perilla oil and α-lipoic acid on lipid metabolism and parameters of oxidative stress. Male rats were fed diets supplemented with 0 or 2.0 g/kg R-α-lipoic acid and containing 120 g/kg of palm (saturated fat), corn (linoleic acid), or perilla oil (α-linolenic acid) for 23 days. Perilla oil compared with other fats decreased serum lipid concentrations in rats fed α-lipoic acid–free diets; however, the combination of perilla oil with α-lipoic acid was ineffective for observing more marked decreases in serum lipid levels. Alterations in hepatic fatty acid synthesis and oxidation may account for the observed changes. Perilla oil, compared with palm and corn oils, strongly increased the malondialdehyde level in the serum and liver. α-Lipoic acid counteracted the increases in these parameters even though the effects were attenuated in the liver. α-Lipoic acid increased the parameters of the anti-oxidant system. The results suggested that α-lipoic acid can ameliorate oxidative stress induced by perilla oil, but the combination of these dietary factors was ineffective for additionally reducing serum lipid levels.     

Liver function parameters,cholesterol, and phospholipid α-linoleic acid are associated with adipokine levels in overweight and obese adults

Dysregulation of adipose hormones in obesity has been associated with the hastened development of metabolic syndrome and associated chronic disease sequalae including cardiovascular disease and type 2 diabetes mellitus. This study aims to identify common biochemical and anthropometric markers that impact adipose hormones, including adiponectin and leptin. Based on previous literature, it was hypothesized that these would be adversely impacted by liver function parameters, and adiponectin levels would be positively correlated with phospholipid Ω-3 fatty acids. Forty nondiabetic adult subjects (body mass index, ≥25.0 kg/m²) were recruited. Fasting plasma samples were taken to assess adipokine levels, glucose metabolism, electrolytes, liver enzymes, and blood lipids. Basic anthropometric measurements were also recorded. Adiponectin levels were positively correlated with high-density lipoprotein cholesterol and negatively correlated with anthropometric measures, insulin, liver enzymes, triglycerides, and very low–density lipoprotein cholesterol but not body mass index. Conversely, plasma leptin levels were positively correlated with anthropometric measures, C-reactive protein, high-density lipoprotein cholesterol, and plasma phospholipid proportions of Ω-3 α linoleic acid but inversely correlated with creatinine levels. These results support other data regarding correlations between adiponectin and relative adipose distribution. Correlations with specific liver enzymes may indicate that adiponectin levels are tied to fatty acid deposition in the liver; however, liver/kidney damage though further mechanistic clarification is required. Leptin levels were associated with measures of adiposity but not liver enzymes. Each of these variables, along with blood lipids, may serve as potential future therapeutic targets for the prevention and management of obesity and related comorbidities.     

Dietary supplementation with a combination of α-lipoic acid,acetyl-l-carnitine,glycerophosphocoline, docosahexaenoic acid,and phosphatidylserine reduces oxidative damage to murine brain and improves cognitive performance

Alzheimer disease has a complex etiology composed of nutritional and genetic risk factors and predispositions. Moreover, genetic risk factors for cognitive decline may remain latent pending age-related decline in nutrition, suggesting the potential importance of early nutritional intervention, including preventative approaches. We hypothesized that a combination of multiple nutritional additives may be able to provide neuroprotection. We demonstrate herein that dietary supplementation with a mixture of ALA, ALCAR, GPC, DHA, and PS reduced reactive oxygen species in normal mice by 57% and prevented the increase in reactive oxygen species normally observed in mice lacking murine ApoE when maintained on a vitamin-free, iron-enriched, oxidative-challenge diet. We further demonstrate that supplementation with these agents prevented the marked cognitive decline otherwise observed in normal mice maintained on this challenge diet. These findings add to the growing body of research indicating that key dietary supplementation may delay the progression of age-related cognitive decline.     

High-fat diet-induced reduction of peroxisome proliferator–activated receptor-γ coactivator-1α messenger RNA levels and oxidative capacity in the soleus muscle of rats with metabolic syndrome

Animal models of type 2 diabetes exhibit reduced peroxisome proliferator–activated receptor-γ coactivator-1α (PGC-1α) messenger RNA (mRNA) levels, which are associated with decreased oxidative capacity, in skeletal muscles. In contrast, animal models with metabolic syndrome show normal PGC-1α mRNA levels. We hypothesized that a high-fat diet decreases PGC-1α mRNA levels in skeletal muscles of rats with metabolic syndrome, reducing muscle oxidative capacity and accelerating metabolic syndrome or inducing type 2 diabetes. We examined mRNA levels and fiber profiles in the soleus muscles of rats with metabolic syndrome (SHR/NDmcr-cp [cp/cp]; CP) fed a high-fat diet. Five-week-old CP rats were assigned to a sedentary group (CP-N) that was fed a standard diet (15.1 kJ/g, 23.6% protein, 5.3% fat, and 54.4% carbohydrates) or a sedentary group (CP-H) that was fed a high-fat diet (21.6 kJ/g, 23.6% protein, 34.9% fat, and 25.9% carbohydrates) and were housed for 10 weeks. Body weight, energy intake, and systolic blood pressure were higher in the CP-H group than in the CP-N group. Nonfasting glucose, triglyceride, total cholesterol, and leptin levels were higher in the CP-H group than in the CP-N group. There was no difference in insulin levels between the CP-N and CP-H groups. Muscle PGC-1α mRNA levels and succinate dehydrogenase activity were lower in the CP-H group than in the CP-N group. We concluded that a high-fat diet reduces PGC-1α mRNA levels and oxidative capacity in skeletal muscles and accelerates metabolic syndrome.