A mathematical analysis of adaptations to the metabolic fate of fructose in essential fructosuria subjects.

Fructose is a major component of Western diets and is implicated in the pathogenesis of obesity and type 2 diabetes. In response to an oral challenge, the majority of fructose is cleared during "first-pass" liver metabolism, primarily via phosphorylation by ketohexokinase (KHK). A rare benign genetic deficiency in KHK, called essential fructosuria (EF), leads to altered fructose metabolism. The only reported symptom of EF is the appearance of fructose in the urine following either oral or intravenous fructose administration. Here we develop and use a mathematical model to investigate the adaptations to altered fructose metabolism in people with EF. First, the model is calibrated to fit available data in normal healthy subjects. Then, to mathematically represent EF subjects, we systematically implement metabolic adaptations such that model simulations match available data for this phenotype. We hypothesize that these modifications represent the major metabolic adaptations present in these subjects. This modeling approach suggests that several other aspects of fructose metabolism, beyond hepatic KHK deficiency, are altered and contribute to the etiology of this benign condition. Specifically, we predict that fructose absorption into the portal vein is altered, peripheral metabolism is slowed, renal reabsorption of fructose is mostly ablated, and alternate pathways for hepatic metabolism of fructose are upregulated. Moreover, these findings have implications for drug discovery and development, suggesting that the therapeutic targeting of fructose metabolism could lead to unexpected metabolic adaptations, potentially due to a physiological response to high-fructose conditions.

Inborn Errors of Fructose Metabolism. What Can We Learn from Them?

Fructose is one of the main sweetening agents in the human diet and its ingestion is increasing globally. Dietary sugar has particular effects on those whose capacity to metabolize fructose is limited. If intolerance to carbohydrates is a frequent finding in children, inborn errors of carbohydrate metabolism are rare conditions. Three inborn errors are known in the pathway of fructose metabolism; (1) essential or benign fructosuria due to fructokinase deficiency; (2) hereditary fructose intolerance; and (3) fructose-1,6-bisphosphatase deficiency. In this review the focus is set on the description of the clinical symptoms and biochemical anomalies in the three inborn errors of metabolism. The potential toxic effects of fructose in healthy humans also are discussed. Studies conducted in patients with inborn errors of fructose metabolism helped to understand fructose metabolism and its potential toxicity in healthy human. Influence of fructose on the glycolytic pathway and on purine catabolism is the cause of hypoglycemia, lactic acidosis and hyperuricemia. The discovery that fructose-mediated generation of uric acid may have a causal role in diabetes and obesity provided new understandings into pathogenesis for these frequent diseases.

Plasma lysosomal enzyme activities in congenital disorders of glycosylation, galactosemia and fructosemia.

BACKGROUND: Variable increases in the plasma activity of different lysosomal enzymes have been reported in patients with congenital disorders of glycosylation (CDG). In particular, elevated plasma aspartylglucosaminidase activity (AGA) has been found in the majority of CDG type I patients. We report on the plasma activity of AGA and other lysosomal enzymes in patients with different types of primary and secondary CDG defects. METHODS: AGA, alpha-mannosidase, beta-mannosidase and beta-hexosaminidase activities were assayed in the plasma of patients with CDGI (4CDGIa, 4CDGIx) and CDGIIx (5, all with a combined N- and O-glycosylation defect), classical galactosemia (GALT) (n=3) and hereditary fructose intolerance (HFI) (n=2). RESULTS: Increased AGA and beta-hexosaminidase activities were found in all and 7/8 of the GDGI patients respectively. All enzymic activities were normal in the CDGIIx patients. Elevated AGA and beta-hexosaminidase activity was also seen in GALT and HFI patients before treatment, when transferrin isoelectric focusing (TfIEF) patterns were also abnormal. CONCLUSIONS: Increased AGA plasma activity, although a consistent finding in CDGI patients, is not specific to this group of disorders since it is also observed in untreated cases of GALT and HFI. Furthermore, plasma AGA activity cannot serve as a marker for CDGII disorders. In conjunction with TfIEF it could be used in the follow up of GALT and HFI patients.

Properties of normal and mutant recombinant human ketohexokinases and implications for the pathogenesis of essential fructosuria.

Alternative splicing of the ketohexokinase (fructokinase) gene generates a "central" predominantly hepatic isoform (ketohexokinase-C) and a more widely distributed ketohexokinase-A. Only the abundant hepatic isoform is known to possess activity, and no function is defined for the lower levels of ketohexokinase-A in peripheral tissues. Hepatic ketohexokinase deficiency causes the benign disorder essential fructosuria. The molecular basis of this has been defined in one family (compound heterozygosity for mutations Gly40Arg and Ala43Thr). Here we show that both ketohexokinase isoforms are indeed active. Ketohexokinase-A has much poorer substrate affinity than ketohexokinase-C for fructose but is considerably more thermostable. The Gly40Arg mutation seems null, rendering both ketohexokinase-A and ketohexokinase-C inactive and largely insoluble. The Ala43Thr mutant retains activity, but this mutation decreases the thermal stability of both ketohexokinase-A and ketohexokinase-C. At physiologic temperature, this results in significant loss of ketohexokinase-C activity but not of ketohexokinase-A. Affected individuals who carry both mutations therefore probably have a selective deficiency of hepatic ketohexokinase, with peripheral ketohexokinase-A being preserved. These findings raise the possibility that ketohexokinase-A serves an unknown physiologic function that remains intact in essential fructosuria. Further mutation analysis in this rare disorder could illuminate the question of whether ketohexokinase-A activity is, unlike that of ketohexokinase-C, physiologically indispensable.

Patients with hereditary fructose intolerance have normal erythrocyte aldolase activity.

Erythrocyte fructose 1,6-bisphosphate aldolase (EC 4.1.2.13) activity was measured in eight children and adults with hereditary fructose intolerance and found to be normal when compared with eleven healthy controls. Therefore, hereditary fructose intolerance cannot be diagnosed by assaying red blood cell aldolase.