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Fructose Metabolism in Cancer.
Krause, N, Wegner, A
Cells. 2020;(12)
Abstract
The interest in fructose metabolism is based on the observation that an increased dietary fructose consumption leads to an increased risk of obesity and metabolic syndrome. In particular, obesity is a known risk factor to develop many types of cancer and there is clinical and experimental evidence that an increased fructose intake promotes cancer growth. The precise mechanism, however, in which fructose induces tumor growth is still not fully understood. In this article, we present an overview of the metabolic pathways that utilize fructose and how fructose metabolism can sustain cancer cell proliferation. Although the degradation of fructose shares many of the enzymes and metabolic intermediates with glucose metabolism through glycolysis, glucose and fructose are metabolized differently. We describe the different metabolic fates of fructose carbons and how they are connected to lipogenesis and nucleotide synthesis. In addition, we discuss how the endogenous production of fructose from glucose via the polyol pathway can be beneficial for cancer cells.
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Fructose and irritable bowel syndrome.
Melchior, C, Douard, V, Coëffier, M, Gourcerol, G
Nutrition research reviews. 2020;(2):235-243
Abstract
Irritable bowel syndrome (IBS) is a chronic disorder characterised by recurrent abdominal pain or discomfort and transit disturbances with heterogeneous pathophysiological mechanisms. The link between food and gastrointestinal (GI) symptoms is often reported by patients with IBS and the role of fructose has recently been highlighted. Fructose malabsorption can easily be assessed by hydrogen and/or methane breath test in response to 25 g fructose; and its prevalence is about 22 % in patients with IBS. The mechanism of fructose-related symptoms is incompletely understood. Osmotic load, fermentation and visceral hypersensitivity are likely to participate in GI symptoms in the IBS population and may be triggered or worsened by fructose. A low-fructose diet could be integrated in the overall treatment strategy, but its role and implication in the improvement of IBS symptoms should be evaluated. In the present review, we discuss fructose malabsorption in adult patients with IBS and the interest of a low-fructose diet in order to underline the important role of fructose in IBS.
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Carbohydrate composition in breast milk and its effect on infant health.
Berger, PK, Plows, JF, Demerath, EW, Fields, DA
Current opinion in clinical nutrition and metabolic care. 2020;(4):277-281
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Abstract
PURPOSE OF REVIEW This narrative review presents the current state of available evidence regarding the role of breast milk carbohydrates on infant outcomes, with a primary focus on growth and body composition. RECENT FINDINGS To date, there is a paucity of available data that exists in this realm. The current literature focuses on the role of two carbohydrate fractions in breast milk, and their relationships with infant outcomes in the first six months of life: oligosaccharides and fructose. A small but growing body of research indicates robust associations of both oligosaccharides and fructose in breast milk with infant weight and length, as well as bone, fat, and lean mass. There is also emerging evidence to support the role of these same carbohydrate fractions in breast milk in infant cognitive development. SUMMARY The present state of the science suggests that oligosaccharides and fructose in breast milk play a role in infant growth and body composition and introduces intriguing associations of these two carbohydrate fractions with infant cognitive development as well.
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Pathobiological and molecular connections involved in the high fructose and high fat diet induced diabetes associated nonalcoholic fatty liver disease.
Ekta, , Gupta, M, Kaur, A, Singh, TG, Bedi, O
Inflammation research : official journal of the European Histamine Research Society ... [et al.]. 2020;(9):851-867
Abstract
BACKGROUND Poor dietary habits such as an over consumption of high fructose and high fat diet are considered as the major culprit for the induction of diabetes associated liver injury. Diabetes mellitus is a metabolic disorder that affects various vital organs of the body especially the kidney, brain, heart, and liver. The high fructose and high fat (HFHF) diet worsen the metabolic conditions by producing various pathogenic burdens such as oxidative stress, inflammation, etc. on liver. The hyperlipidemic and hyperglycemic conditions induced by HFHF diet leads to the generation of various proinflammatory mediators like TNFα, interleukin and cytokines. AIM AND METHODS The systematic bibliographical literature survey was done with the help of PubMed, Google scholar and MedLine to identify all pathological and molecular concerened with HFHF induced diabetic liver injury. The consumption of HFHF diet leads to an increase in mitochondrial oxidative stress thereby decreases the liver protective antioxidants required for cell viability. HFHF diet disturbs lipid and lipoprotein clearance by elevating the level of apolipoprotein CIII and impairing the hydrolysis of triglyceride. As a result, there is an increase in free fatty acid concentration, triglycerides and diacylglycerol in the liver which further triggers the situation of insulin resistance. CONCLUSION The focus of present review is based upon the various pathological, genetic and molecular mechanism involved in the development of high-fat high fructose diet induced diabetic liver injury. However, the current review also documented few shreds of evidence related to various microRNAs (miR-31, miR-33a, miR-34a, miR-144, miR-146b, miR-150) concerned to HFHF diet which play an important role in the pathogenesis of diabetes associated liver injury Dietary life style modification may prove beneficial in the management of various metabolic disorders.
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Fructose co-ingestion to increase carbohydrate availability in athletes.
Fuchs, CJ, Gonzalez, JT, van Loon, LJC
The Journal of physiology. 2019;(14):3549-3560
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Abstract
Carbohydrate availability is important to maximize endurance performance during prolonged bouts of moderate- to high-intensity exercise as well as for acute post-exercise recovery. The primary form of carbohydrates that are typically ingested during and after exercise are glucose (polymers). However, intestinal glucose absorption can be limited by the capacity of the intestinal glucose transport system (SGLT1). Intestinal fructose uptake is not regulated by the same transport system, as it largely depends on GLUT5 as opposed to SGLT1 transporters. Combining the intake of glucose plus fructose can further increase total exogenous carbohydrate availability and, as such, allow higher exogenous carbohydrate oxidation rates. Ingesting a mixture of both glucose and fructose can improve endurance exercise performance compared to equivalent amounts of glucose (polymers) only. Fructose co-ingestion can also accelerate post-exercise (liver) glycogen repletion rates, which may be relevant when rapid (<24 h) recovery is required. Furthermore, fructose co-ingestion can lower gastrointestinal distress when relatively large amounts of carbohydrate (>1.2 g/kg/h) are ingested during post-exercise recovery. In conclusion, combined ingestion of fructose with glucose may be preferred over the ingestion of glucose (polymers) only to help trained athletes maximize endurance performance during prolonged moderate- to high-intensity exercise sessions and accelerate post-exercise (liver) glycogen repletion.
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Bioelectrocatalytic performance of d-fructose dehydrogenase.
Adachi, T, Kaida, Y, Kitazumi, Y, Shirai, O, Kano, K
Bioelectrochemistry (Amsterdam, Netherlands). 2019;:1-9
Abstract
This review summarizes the bioelectrocatalytic properties of d-fructose dehydrogenase (FDH), while taking into consideration its enzymatic characteristics. FDH is a membrane-bound flavohemo-protein with a molecular mass of 138 kDa, and it catalyzes the oxidation of d-fructose to 5-keto-d-fructose. The characteristic feature of FDH is its strong direct-electron-transfer (DET)-type bioelectrocatalytic activity. The pathway of the DET-type reaction is discussed. An overview of the application of FDH-based bioelectrocatalysis to biosensors and biofuel cells is also presented, and the benefits and problems associated with it are extensively discussed.
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New advances in renal mechanisms of high fructose-induced salt-sensitive hypertension.
Xu, CM, Yang, TX
Sheng li xue bao : [Acta physiologica Sinica]. 2018;(6):581-590
Abstract
Fructose intake has increased dramatically over the past century and the upward trend has continued until recently. Increasing evidence suggests that the excessive intake of fructose induces salt-sensitive hypertension. While the underlying mechanism is complex, the kidney likely plays a major role. This review will highlight recent advances in the renal mechanisms of fructose-induced salt-sensitive hypertension, including (pro)renin receptor-dependent activation of intrarenal renin-angiotensin system, increased nephron Na+ transport activity via sodium/hydrogen exchanger 3 and Na/K/2Cl cotransporter, increased renal uric acid production, decreased renal nitric oxide production, and increased renal reactive oxygen species production, and suggest actions based on these mechanisms that have therapeutic implications.
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Dietary carbohydrates and fatty liver disease: de novo lipogenesis.
Chiu, S, Mulligan, K, Schwarz, JM
Current opinion in clinical nutrition and metabolic care. 2018;(4):277-282
Abstract
PURPOSE OF REVIEW To review recent evidence for the role of dietary carbohydrate in de novo lipogenesis (DNL) and nonalcoholic fatty liver disease (NAFLD). RECENT FINDINGS A large body of evidence suggests that increased hepatic DNL is a significant pathway contributing to the development of NAFLD. Dietary carbohydrates, in particular, fructose, have been shown to stimulate DNL and increase liver fat, although it is debated whether this is due to excess energy or fructose per se. Recent dietary intervention studies conducted in energy balance show that high-fructose diets increase DNL and liver fat, whereas fructose restriction decreases DNL and liver fat. SUMMARY The association of high-carbohydrate and high-sugar diets with NAFLD may in part be explained by the effect of sugar on increasing hepatic DNL.
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Fructose metabolism, cardiometabolic risk, and the epidemic of coronary artery disease.
Mirtschink, P, Jang, C, Arany, Z, Krek, W
European heart journal. 2018;(26):2497-2505
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Abstract
Despite strong indications that increased consumption of added sugars correlates with greater risks of developing cardiometabolic syndrome (CMS) and cardiovascular disease (CVD), independent of the caloric intake, the worldwide sugar consumption remains high. In considering the negative health impact of overconsumption of dietary sugars, increased attention is recently being given to the role of the fructose component of high-sugar foods in driving CMS. The primary organs capable of metabolizing fructose include liver, small intestine, and kidneys. In these organs, fructose metabolism is initiated by ketohexokinase (KHK) isoform C of the central fructose-metabolizing enzyme KHK. Emerging data suggest that this tissue restriction of fructose metabolism can be rescinded in oxygen-deprived environments. In this review, we highlight recent progress in understanding how fructose metabolism contributes to the development of major systemic pathologies that cooperatively promote CMS and CVD, reference recent insights into microenvironmental control of fructose metabolism under stress conditions and discuss how this understanding is shaping preventive actions and therapeutic approaches.
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Fructose, Glucocorticoids and Adipose Tissue: Implications for the Metabolic Syndrome.
Legeza, B, Marcolongo, P, Gamberucci, A, Varga, V, Bánhegyi, G, Benedetti, A, Odermatt, A
Nutrients. 2017;(5)
Abstract
The modern Western society lifestyle is characterized by a hyperenergetic, high sugar containing food intake. Sugar intake increased dramatically during the last few decades, due to the excessive consumption of high-sugar drinks and high-fructose corn syrup. Current evidence suggests that high fructose intake when combined with overeating and adiposity promotes adverse metabolic health effects including dyslipidemia, insulin resistance, type II diabetes, and inflammation. Similarly, elevated glucocorticoid levels, especially the enhanced generation of active glucocorticoids in the adipose tissue due to increased 11β-hydroxysteroid dehydrogenase 1 (11β-HSD1) activity, have been associated with metabolic diseases. Moreover, recent evidence suggests that fructose stimulates the 11β-HSD1-mediated glucocorticoid activation by enhancing the availability of its cofactor NADPH. In adipocytes, fructose was found to stimulate 11β-HSD1 expression and activity, thereby promoting the adipogenic effects of glucocorticoids. This article aims to highlight the interconnections between overwhelmed fructose metabolism, intracellular glucocorticoid activation in adipose tissue, and their metabolic effects on the progression of the metabolic syndrome.