Dietary intake of sugars containing fructose has dramatically increased in our society with one-sixth of the population eating 25% of their diet or more. While attempts to reduce sugar intake are now recommended, it is very difficult to avoid exposure to HFCS and sucrose in today's culture. One group that suffers from the widespread use of added sugars are individuals with Hereditary Fructose Intolerance (HFI), an autosomal recessive whose subjects develop severe reactions following fructose ingestion, with abdominal pain, vomiting, diarrhea, symptomatic hypoglycemia, hyperuricemia, and even death in children. Fructose metabolism is initiated by two enzymes, fructokinase that phosphorylates fructose to fructose-1- phosphate causing ATP depletion and uric acid generation, and aldolase b that further splits the fructose-1- phosphate molecule into dihydroacetone phosphate and glyceraldehyde. HFI is caused by the mutation in aldolase B leading to accumulation of fructose-1-phosphate, marked ATP depletion and uric acid generation following fructose ingestion that is much greater than that observed in normal individuals. Our preliminary data in aldolase b deficient mice suggest that upon exposure to fructose -in diet or endogenously produced-, its deficiency is associated with fructokinase hyperactivation, growth retardation, severe hypoglycemia, liver/intestinal injury and death which are completely blocked when fructokinase is inhibited. Of interest, the deleterious effects observed in aldolase b deficient mice are exacerbated when mice are hyperuricemic suggesting an important deleterious role of uric acid in the pathogenesis of HFI. These observation led us to our overall hypothesis that the blockade of fructose metabolism to fructose-1- phosphate protects against HFI in subjects with aldolase b deficiency. Specifically, we propose that 1) fructokinase knockout mice with aldolase b deficiency will not develop HFI upon exposure to fructose, 2) the blockade of endogenous fructose production by inhibition of aldose reductase and the polyol pathway is clinically relevant for people with aldolase b deficiency and 3) lowering uric acid production and accumulation is an important therapeutic approach in the prevention and treatment of HFI. The studies proposed in this application are clinically relevant as they will provide insights into future therapies (targeting fructokinase, aldose reductase, AMP deaminase and/or xanthine oxidase) for this disease in which the only treatment (avoidance of fructose) has become almost impossible in our society. The applicant will count with an excellent group of collaborators that include Drs. Dean Tolan -a world expert in clinical hereditary fructose intolerance- and Richard Johnson -a renowned scientist in the field of sugar and fructose metabolism-. This award will allow the applicant as an early stage investigator (ESI) to develop the skills necessary and the financial needs to fully become an independent scientist and will provide for intellectual development through both didactic programs and by facilitating interactions with a variety of researchers in different departments.
Hereditary fructose intolerance is a very severe disease characterized by symptomatic hypoglycemia, liver failure and death in response to fructose with no treatment and that results as a consequence of an inborn mutation in the aldolase b gene thus causing the accumulation of fructose-1-phosphate, ATP depletion, uric acid accumulation and the hyperactivation of fructokinase. Our preliminary data in aldolase b deficient mice suggest that blocking fructokinase, we can prevent the development of all pathogenic effects associated to acute and chronic exposure to fructose in these mice. Based on these observations, we hypothesize that the pharmacological inhibition of fructokinase could be clinically relevant as a mean to prevent HFI and will provide for the first time, an efficient treatment for subjects with aldolase b deficiency.
Lanaspa, Miguel A; Andres-Hernando, Ana; Orlicky, David J et al. (2018) Ketohexokinase C blockade ameliorates fructose-induced metabolic dysfunction in fructose-sensitive mice. J Clin Invest 128:2226-2238 |
Lanaspa, Miguel A; Kuwabara, Masanari; Andres-Hernando, Ana et al. (2018) High salt intake causes leptin resistance and obesity in mice by stimulating endogenous fructose production and metabolism. Proc Natl Acad Sci U S A 115:3138-3143 |
Cara-Fuentes, Gabriel; Lanaspa, Miguel A; Garcia, Gabriela E et al. (2018) Urinary CD80: a biomarker for a favorable response to corticosteroids in minimal change disease. Pediatr Nephrol 33:1101-1103 |
Doke, Tomohito; Ishimoto, Takuji; Hayasaki, Takahiro et al. (2018) Lacking ketohexokinase-A exacerbates renal injury in streptozotocin-induced diabetic mice. Metabolism 85:161-170 |
Jensen, Thomas; Abdelmalek, Manal F; Sullivan, Shelby et al. (2018) Fructose and sugar: A major mediator of non-alcoholic fatty liver disease. J Hepatol 68:1063-1075 |
Andres-Hernando, Ana; Li, Nanxing; Cicerchi, Christina et al. (2017) Protective role of fructokinase blockade in the pathogenesis of acute kidney injury in mice. Nat Commun 8:14181 |
Johnson, Richard J; Sánchez-Lozada, Laura G; Andrews, Peter et al. (2017) Perspective: A Historical and Scientific Perspective of Sugar and Its Relation with Obesity and Diabetes. Adv Nutr 8:412-422 |