Download PDF
Horm Metab Res 2010; 42(12): 868-873
DOI: 10.1055/s-0030-1265145
Humans, Clinical

© Georg Thieme Verlag KG Stuttgart · New York

Metabolism of Fructose to Oxalate and Glycolate

J. Knight1 , D. G. Assimos1 , L. Easter2 , R. P. Holmes1
  • 1Department of Urology, Wake Forest University School of Medicine, Winston-Salem, NC, USA
  • 2Clinical Research Unit, Wake Forest University School of Medicine, Winston-Salem, NC, USA
Further Information

Publication History

received 16.06.2010

accepted 17.08.2010

Publication Date:
14 September 2010 (online)

Also available at
    Permissions and Reprints

Abstract

Much attention has been recently directed at fructose consumption because of its association with obesity and subsequent development of chronic diseases. It was recently reported that an increased fructose intake increases the risk of forming kidney stones. It was postulated that fructose consumption may increase urinary oxalate, a risk factor for calcium oxalate kidney stone disease. However, conflicting results have been obtained in human studies examining the relationship between fructose metabolism and oxalate synthesis. To test whether fructose intake influences urinary excretions impacting kidney stone risk, healthy subjects consumed diets controlled in their contents of fructose, oxalate, calcium, and other nutrients. Subjects consumed diets containing 4, 13, and 21% of calories as fructose in a randomized order. No changes in the excretions of oxalate, calcium, and uric acid were observed. In vitro investigations with cultured liver cells incubated with 13C-labeled sugars indicated that neither fructose nor glucose was converted to oxalate by these cells. Fructose metabolism accounted for 12.4±1.6% of the glycolate detected in the culture medium and glucose 6.4±0.9%. Our results suggest that mechanisms for stone risk associated with fructose intake may lie in factors other than those affecting the major stone risk parameters in urine.

Key words

nutrition - urolithiasis - HepG2 cells - glyoxal - glucose

References

  • 1 Assimos DG, Holmes RP. Role of diet in the therapy of urolithiasis.  Urol Clin North Amer. 2000;  27 255-268
    Google Scholar
  • 2 Taylor EN, Curhan GC. Diet and fluid prescription in stone disease.  Kidney Int. 2006;  70 835-839
    Google Scholar
  • 3 Taylor EN, Fung TT, Curhan GC. DASH-style diet associates with reduced risk for kidney stones.  J Am Soc Nephrol. 2009;  20 2253-2259
    Google Scholar
  • 4 Taylor EN, Curhan GC. Fructose consumption and the risk of kidney stones.  Kidney Int. 2008;  73 207-212
    Google Scholar
  • 5 Milne DB, Nielsen FH. The interaction between dietary fructose and magnesium adversely affects macromineral homeostasis in men.  J Am Coll Nutr. 2000;  19 31-37
    Google Scholar
  • 6 Nguyen NU, Dumoulin G, Henriet M-T, Regnard J. Increase in urinary calcium and oxalate after fructose infusion.  Horm Metab Res. 1995;  27 155-158
    Google Scholar
  • 7 Fox IH, Kelley WN. Studies on the mechanism of fructose-induced hyperuricemia in man.  Metabolism. 1972;  21 713-721
    Google Scholar
  • 8 Abate N, Chandalia M, Cabo-Chan Jr AV, Moe OW, Sakhaee K. The metabolic syndrome and uric acid nephrolithiasis: novel features of renal manifestation of insulin resistance.  Kidney Int. 2004;  65 386-392
    Google Scholar
  • 9 Curhan GC, Taylor EN. 24-h uric acid excretion and the risk of kidney stones.  Kidney Int. 2008;  73 489-496
    Google Scholar
  • 10 Sakhaee K. Recent advances in the pathophysiology of nephrolithiasis.  Kidney Int. 2009;  75 585-595
    Google Scholar
  • 11 Nguyen NU, Dumoulin G, Wolf JP, Berthelay S. Urinary calcium and oxalate excretion during oral fructose or glucose load in man.  Horm Metab Res. 1989;  21 96-99
    Google Scholar
  • 12 Steinmann B, Gitzelmann R, Berghe GVD. Disorders of fructose metabolism. In: Scriver CR, Beaudet AL, Sly WS, Valle D, (eds). The Metabolic and Molecular Bases of Inherited Disease. 8th ed New York: McGraw-Hill; 2001: 1489-1520
    Google Scholar
  • 13 Conyers RAJ, Bais R, Rofe AM. The relation of clinical catastrophes, endogenous oxalate production, and urolithiasis.  Clin Chem. 1990;  36 1717-1730
    Google Scholar
  • 14 Baker PR, Cramer SD, Kennedy M, Assimos DG, Holmes RP. Glycolate and glyoxylate metabolism in HepG2 cells.  Amer J Physiol. 2004;  287 C1359-C1365
    Google Scholar
  • 15 Javitt NB. Hep G2 cells as a resource for metabolic studies: lipoprotein, cholesterol, and bile acids.  FASEB J. 1990;  4 161-168
    Google Scholar
  • 16 Rofe AM, James HM, Bais R, Conyers RAJ. The production of [14C] oxalate during the metabolism of [14C] carbohydrates in isolated rat hepatocytes.  Austral J Exp Biol Med Sci. 1980;  58 103-116
    Google Scholar
  • 17 Holmes RP, Assimos DG. Glyoxylate synthesis, and its modulation and its influence on oxalate synthesis.  J Urol. 1998;  160 1617-1624
    Google Scholar
  • 18 Knight J, Jiang J, Assimos DG, Holmes RP. Hydroxyproline ingestion and urinary oxalate and glycolate excretion.  Kidney Int. 2006;  70 1929-1934
    Google Scholar
  • 19 Holbrook JT, Smith Jr JC, Reiser S. Dietary fructose or starch: effects on copper, zinc, iron, manganese, calcium, and magnesium balances in humans.  Am J Clin Nutr. 1989;  49 1290-1294
    Google Scholar
  • 20 Barngrover DA, Stevens HC, Dills WL. d-Xylulose-1-phosphate: enzymatic assay and production in isolated rat hepatocytes.  Biochem Biophys Res Commun. 1981;  102 75-80
    Google Scholar
  • 21 Kraemer RJ, Deitrich RA. Isolation and charcterization of human liver aldehyde dehydrogenase.  J Biol Chem. 1968;  243 6402-6408
    Google Scholar
  • 22 Thornalley PJ. Glyoxalase I – structure, function and a critical role in the enzymatic defence against glycation.  Biochem Soc Trans. 2003;  31 1343-1348
    Google Scholar
  • 23 Shangari N, Bruce WR, Poon R, O'Brien PJ. Toxicity of glyoxals – role of oxidative stress, metabolic detoxification and thiamine deficiency.  Biochem Soc Trans. 2003;  31 1390-1393
    Google Scholar
  • 24 Chang SH, Garcia J, Melendez JA, Kilberg MS, Agarwal A. Haem oxygenase 1 gene induction by glucose deprivation is mediated by reactive oxygen species via the mitochondrial electron-transport chain.  Biochem J. 2003;  371 877-885
    Google Scholar
  • 25 Emmerson BT. Effect of oral fructose on urate production.  Ann Rheum Dis. 1974;  33 276-280
    Google Scholar
  • 26 Stirpe F, Della Corte E, Bonetti E, Abbondanza A, Abbati A, De Stefano F. Fructose-induced hyperuricaemia.  Lancet. 1970;  2 1310-1311
    Google Scholar
  • 27 Hallfrisch J. Metabolic effects of dietary fructose.  FASEB J. 1990;  4 2652-2660
    Google Scholar
  • 28 Narins RG, Weisberg JS, Myers AR. Effects of carbohydrates on uric acid metabolism.  Metabolism. 1974;  23 455-465
    Google Scholar
  • 29 Evan AP, Lingeman JE, Coe FL, Parks JH, Bledsoe SB, Shao Y, Sommer AJ, Paterson RF, Kuo RL, Grynpas M. Randall's plaque of patients with nephrolithiasis begins in basement membranes of thin loops of Henle.  J Clin Invest. 2003;  111 607-616
    Google Scholar
  • 30 Bergstra AE, Lemmens AG, Beynen AC. Dietary fructose vs. glucose stimulates nephrocalcinogenesis in female rats.  J Nutr. 1993;  123 1320-1327
    Google Scholar

Correspondence

J. Knight

Department of Urology

Wake Forest University School

of Medicine

Medical Center Blvd

Winston-Salem NC 27157

USA

Phone: +1/336/716 1391

Fax: +1/336/716 0174

Email: jknight@wfubmc.edu