Vergleich der Vitamin- und Antioxidans-Wirkung der verschiedenen Tocopherole bei den wichtigsten Pflanzenölen

Genetic possibilities for altering sunflower oil quality to obtain novel oils

The sunflower is one of the four most important oilseed crops in the world, and the nutritional quality of its edible oil ranks among the best vegetable oils in cultivation. Typically up to 90% of the fatty acids in conventional sunflower oil are unsaturated, namely oleic (C 18:1, 16%-19%) and linoleic (C 18:2, 68%-72%) fatty acids. Palmitic (C 16:0, 6%), stearic (C 18:0, 5%), and minor amounts of myristic (C 14:0), myristoleic (C 14:1), palmitoleic (C 16:1), arachidic (C 20:0), behenic (C 22:0), and other fatty acids account for the remaining 10%. Advances in modern genetics, most importantly induced mutations, have altered the fatty acid composition of sunflower oil to a significant extent. Treating sunflower seeds with gamma- and X-rays has produced mutants with 25%-30% palmitic acid. Sunflower seed treatment with X-rays has also resulted in mutants having 30% palmitoleic acid, while treatments with mutagenic sodium azide have produced seeds containing 35% stearic acid. The most important mutations have been obtained by treatment with dimethyl sulfate, which produced genotypes with more than 90% oleic acid. Mutants have also been obtained that have a high linoleic acid content (>80%) by treating seeds with X-rays and ethyl methanesulfonate. Of the vitamin E family of compounds, sunflower oil is known to predominantly contain alpha-tocopherol (>90%). Spontaneous mutations controlled by recessive genes have been discovered that significantly alter tocopherol forms and levels. The genes in question are tph(1) (50% alpha- and 50% beta-tocopherol), tph(2) (0%-5% alpha- and 95%-100% gamma-tocopherol), and tph(1)tph(2) (8%-40% alpha-, 0%-25% beta-, 25%-84% gamma-, and 8%-50% delta-tocopherol). The existence of (mutant) genes for increased levels of individual fatty acids and for different forms and levels of tocopherol enables the development of sunflower hybrids with different oil quality. The greatest progress has been made in developing high-oleic hybrids (>90% oleic acid). There has been considerable work done recently on the development of high-oleic hybrids with altered tocopherol levels, the oil of which will have 10-20 times greater oxidative stability than that of conventional sunflower oil. While sunflower breeders work on developing hybrids with altered oil quality, medical scientists in general and nutritionists in particular will determine the parameters for the use of these novel types of oil that can improve human nutrition and be used in the prevention of cardiovascular diseases.

The biological activity of natural source tocopherols in chickens fed fresh or oxidized fat rich in linoleic acid

Three experiments were carried out with male broiler chickens reared from day- old to 6 weeks of age on semi-purified diets containing 10% fresh (Expt. 1 and 3) or oxidized (Expt. 2) re-esterified triglycerides with a fatty acid composition similar to that of soya bean oil containing increasing concentrations of either a mixture of d-alpha-, gamma-, delta-tocopherylacetate (d-tocopherols) of natural source or dl-alpha- tocopheryl acetate (dl-tocopherol). In Expt. 1 and 2 the mixture of d-tocopherols consisted of 35.7% d-alpha-, 45.3% d-gamma- and 19.0% d-delta-, while in Expt. 3 the distribution was 25.3% d-alpha-, 28.1% d-gamma- and 10.8% d-gamma- in 35.8% re-esterified triglycerides. The relative biopotency of d-alpha-: gamma-: delta-tocopherol was anticipated to be 100:25:1, whereas that of dl-alpha-tocopherol was 74% relative to d-alpha-tocopherol. The experiments demonstrate that the results obtained for the biological activity depend on the response parameters chosen. With respect to gain in weight, feed conversion, relative organ weight, packed cell volume (PCV), ELP (erythrocyte lipid peroxidation), plasma activities of glutamate-oxaloacetate-transaminase (GOT), creatine kinase (CK) and glutathione peroxidase (GSH-Px) and plasma Na+ concentration, the mixture of natural source tocopherols was identical to that of dl-alpha-tocopheryl acetate, although the concentration of alpha-tocopherol was only about one third of that of dl-alpha-tocopherol. Differences between natural source and synthetic tocopherols were expectedly observed with respect to plasma concentrations of alpha-, gamma-, delta-tocopherol. Differences between the two forms as to muscular dystrophy, in vitro haemolysis and potassium concentration in plasma were ambiguous. It is suggested that the function of d-alpha-, gamma-, delta-tocopherol in erythrocyte fragility and skeletal muscle structure should be compared to that of dl-alpha-tocopherol in future investigations.

[Significance of nonsaponifiable constituents of dietary fats on the bioactivity of vitamin E]

In experiments with male Wistar rats the influence of the non-saponifiable constituents of dietary fats: dl-alpha-tocopherol (60 ppm), dl-gamma-tocopherol (480 ppm), ubiquinone (96 ppm) and beta-sitosterol (3035 ppm) on the tocopherol status was investigated, considering the fatty acid composition of the tested fats. For a test period of eight weeks the animals were fed isoenergetic diets containing three types of dietary fats: corn oil (60% PUFA), a kind of "stripped corn oil" (60% PUFA) and butter (nearly 5% PUFA). Independent of the PUFA-content of the diet, the tocopherol supplementations were able to stabilize the erythrocyte membrane; the calculated hemolysis rates were about 2%. The absence of tocopherols in the diets ("stripped corn oil", butter) caused an increase of the hemolysis rate up to 70% after two weeks. The original amounts of tocopherols in corn oil tended to minimize the hemolysis. Ubiquinone and beta-sitosterol did not reduce the hemolysis rates when they were applied without tocopherols. With respect to creatine-phosphokinase activity, creatine and creatinine excretion the results were similar. Plasma and erythrocyte levels of alpha- and gamma-tocopherol were determined in all groups and discussed in connection with the other examined parameters of tocopherol status. The ultimate result of this experiment is that the content of tocopherols in dietary fats is not always adequate to keep vitamin E status normal, especially if polyunsaturated fatty acid content is high in the diet. Reflecting the vitamin E adequacy of dietary fats, not only alpha-tocopherol but also gamma-tocopherol should be much more considered than previously.