Modulación por Passiflora edulis de triglicéridos y colesterol intracelulares en líneas celulares de cáncer colorrectal SW480 y sus derivadas metastásicas (SW620) / Modulation by Passiflora edulis of intracellular triglycerides and cholesterol in SW480 col orectal cancer cell lines and their metastatic derivatives (SW620)

Cancer cells modify lipid metabolism to proliferate, Passiflora edulis ( P. edulis ) fruit juice (ZuFru) has antitumor activity, but whether a mechanism is through modulation of cell lipids is unknown. T o establish if ZuFru modifies cholesterol and triglycerides in SW480 and SW620. ZuFru composition was studied by phytochemical march; antiproliferative activity by sulforhodamine B, cholesterol , and triglycerides by Folch method. Z ufru contains anthocyanins, flavonoids, alkaloids , and tannins. Cell lines showed differences in their growth rate ( p =0.049). At 39.6 µg/m L of ZuFru, cell viability was decreased: SW480 (45.6%) and SW620 (45.1%). In SW480, cholesterol (44.6%) and triglycerides (46.5%) decreased; In SW620, cholesterol decreased 14.8% and triglycerides increased 7%, with significant differences for both lines. A ntiproliferative activity of ZuFru could be associated with the inhibition of intracellular biosynthesis of cholesterol and triglycerides in SW480. Action mechanisms need to be further investigated.

Las células cancerosas modifican el metabolismo lipídico para proliferar; el zumo de fruta (ZuFru) de Passiflora edulis ( P. edulis ) tiene activida d antitumoral, sin embargo, se desconoce si se involucran los lípidos celulares. E stablecer si ZuFru modifica colesterol y triglicéridos en células SW480 y SW620. C omposición del ZuFru, actividad antiproliferativa, colesterol y triglicéridos. Se encontraro n antocianinas, flavonoides, alcaloides y taninos. Las líneas celulares mostraron diferencias en su tasa de crecimiento ( p =0 . 049); ZuFru 39,6 µg/ml se disminuyó la viabilidad celular; SW480 (45,6%) y SW620 (45,1%); en SW480 colesterol (44,6%) y triglicérid os (46,5%) en SW620, colesterol (14,8%) y los triglicéridos aumentaron 7%, con diferencias significativas para ambas líneas. La actividad antiproliferativa del ZuFru podría estar asociada a la inhibición de la biosíntesis intracelular de colesterol y de tr iglicéridos en SW480, pero no en SW620. Estos mecanismos de acción deben ser fuertemente investigados.

Chemical Composition of Mango (Mangifera indica L.) Fruit: Nutritional and Phytochemical Compounds.

Mango fruit has a high nutritional value and health benefits due to important components. The present manuscript is a comprehensive update on the composition of mango fruit, including nutritional and phytochemical compounds, and the changes of these during development and postharvest. Mango components can be grouped into macronutrients (carbohydrates, proteins, amino acids, lipids, fatty, and organic acids), micronutrients (vitamins and minerals), and phytochemicals (phenolic, polyphenol, pigments, and volatile constituents). Mango fruit also contains structural carbohydrates such as pectins and cellulose. The major amino acids include lysine, leucine, cysteine, valine, arginine, phenylalanine, and methionine. The lipid composition increases during ripening, particularly the omega-3 and omega-6 fatty acids. The most important pigments of mango fruit include chlorophylls (a and b) and carotenoids. The most important organic acids include malic and citric acids, and they confer the fruit acidity. The volatile constituents are a heterogeneous group with different chemical functions that contribute to the aromatic profile of the fruit. During development and maturity stages occur important biochemical, physiological, and structural changes affecting mainly the nutritional and phytochemical composition, producing softening, and modifying aroma, flavor, and antioxidant capacity. In addition, postharvest handling practices influence total content of carotenoids, phenolic compounds, vitamin C, antioxidant capacity, and organoleptic properties.