The metabolic syndrome has recently been recognized as a risk factor for kidney disease, but the mechanisms mediating this risk remain unclear. High fructose consumption by animals produces a model of the metabolic syndrome with hypertension, hyperlipidemia, and insulin resistance. The present study was conducted to test the hypothesis that consumption of a high-fructose diet could accelerate the progression of chronic kidney disease. Three groups of 14 male Sprague-Dawley rats were pair fed a specialized diet containing 60% fructose (FRU) or 60% dextrose (DEX) or standard rat chow (CON). After the animals were fed their assigned diet for 6 wk, five-sixths nephrectomy was performed, and the assigned diet was continued for 11 wk. Proteinuria was significantly increased and creatinine clearance was decreased in the FRU group compared with the CON and DEX groups, and blood urea nitrogen was higher in the FRU group than in the CON and DEX groups. Kidneys from the FRU group were markedly larger than kidneys from the CON and DEX groups. Glomerular sclerosis, tubular atrophy, tubular dilatation, and cellular infiltration appeared markedly worse in kidneys from the FRU group than in kidneys from the DEX and CON groups. Monocyte chemoattractant protein-1 (MCP-1) was measured in renal tissue homogenate and found to be increased in the FRU group. In vitro studies were conducted to determine the mechanism for increased renal MCP-1, and fructose stimulation of proximal tubular cells resulted in production of MCP-1. In conclusion, consumption of a high-fructose diet greatly accelerates progression of chronic kidney disease in the rat remnant kidney model. metabolic syndrome; high-fructose corn syrup; monocyte chemoattractant protein-1
Metabolic syndrome, characterized by truncal obesity, hypertriglyceridemia, elevated BP, and insulin resistance, is recognized increasingly as a major risk factor for kidney disease and also is a common feature of patients who are on dialysis. One feature that is common to patients with metabolic syndrome is an elevated uric acid. Although often considered to be secondary to hyperinsulinemia, recent evidence supports a primary role for uric acid in mediating this syndrome. Specifically, fructose, which rapidly can cause metabolic syndrome in rats, also raises uric acid, and lowering uric acid in fructose-fed rats prevents features of the metabolic syndrome. Uric acid also can accelerate renal disease in experimental animals and epidemiologically is associated with progressive renal disease in humans. It is proposed that fructose-and purine-rich foods that have in common the raising of uric acid may have a role in the epidemic of metabolic syndrome and renal disease that is occurring throughout the world.J Am Soc Nephrol 17: S165-S168, . doi: 10.1681 T he metabolic syndrome is defined as a syndrome of truncal obesity, insulin resistance, elevated BP, hypertriglyceridemia, and hyperuricemia (Table 1) (1-4). The prevalence of metabolic syndrome has been increasing at an alarming rate throughout the world. In the United States, the current prevalence is estimated to be 27% (29% in women and 25.2% in men) (5); in Europe, it is 15.7% in men and 14.2% in women (6); and in China it is 13.7% (9.8% in men and 17.8% in women) (7).The presence of metabolic syndrome is strongly associated with the development of diabetes (8), hypertension (9), cardiovascular disease (10), and all-cause mortality (11). However, recent studies have emphasized that metabolic syndrome also is both associated with and a risk for the development of chronic kidney disease (CKD). For example, in a recent study, the metabolic syndrome was found to be strongly correlated with CKD (defined as GFR Ͻ60 ml/min) and microalbuminuria, and the risk increased progressively with the number of criteria constituting the syndrome (12). In another study of Native Americans without diabetes, a positive relationship was identified between microalbuminuria and features of the metabolic syndrome (13).The mechanism(s) by which metabolic syndrome might accelerate renal disease remains unclear. One possibility relates to the presence of obesity itself. Obesity has been found to be an independent risk factor for CKD (12,14), and treating obesity might stabilize renal function (15) or reverse early hemodynamic abnormalities and glomerular dysfunction (16). Obesity has been associated with a type of focal segmental glomerulosclerosis (FSGS) called "obesity-related glomerulopathy" (17).Hall et al. (18) proposed that lipid deposition in the inner medulla increases intrarenal pressure, leading to decreased tubular flow, which results in increased sodium reabsorption in Henle loop, volume expansion, and the development of systemic hypertension. Obesity also increases the risk...
Fructose is a commonly used sweetener associated with diets that increase the prevalence of metabolic syndrome. Thiazide diuretics are frequently used in these patients for treatment of hypertension, but they also exacerbate metabolic syndrome. Rats on high-fructose diets that are given thiazides exhibit potassium depletion and hyperuricemia. Potassium supplementation improves their insulin resistance and hypertension, whereas allopurinol reduces serum levels of uric acid and ameliorates hypertension, hypertriglyceridemia, hyperglycemia, and insulin resistance. Both potassium supplementation and treatment with allopurinol also increase urinary nitric oxide excretion. We suggest that potassium depletion and hyperuricemia in rats exacerbates endothelial dysfunction and lowers the bioavailability of nitric oxide, which blocks insulin activity and causes insulin resistance during thiazide usage. Addition of potassium supplements and allopurinol with thiazides might be helpful in the management of metabolic syndrome. The metabolic syndrome (MS) is a constellation of risk factors for cardiovascular disease and type 2 diabetes and consists of abdominal obesity, hypertriglyceridemia, low HDL cholesterol, high BP, insulin resistance, and hyperglycemia. 1,2 Endothelial dysfunction and hyperuricemia also are closely associated with MS. 3,4 Hydrochlorothiazide (HCTZ) is beneficial in patients with hypertension because it reduces morbidity and mortality, especially the frequency of stroke and congestive heart failure. 5,6 As a result, thiazides are recommended as the first-line therapy for hypertension. 6 However, many patients with hypertension have MS. In turn, HCTZ usage, although critical in the management of hypertension, can have several adverse effects, such as electrolyte disorders (hypokalemia, hyponatremia, and hypomagnesemia), hyperuricemia, hyperlipidemia, and impairment of glucose metabolism in addition to volume depletion. 7-10 These adverse effects result in the development or exacerbation of MS. Although low-dosage thiazides have led to a reduction of these adverse effects, they increase the incidence of new onset of diabetes 9 and can be associated with hypokalemia, hyperuricemia, and hyperlipidemia. 11 Understanding the precise mechanisms by which HCTZ exacerbates MS is important. Some evidence suggests that thiazide-induced hypokalemia may mediate insulin resistance. 12,13 In addition, experimental hyperuricemia can cause endothelial dysfunction, 3,14 hypertension, 15 and hyperinsulinemia. 3,16 Furthermore, we recently reported that hyperuricemia causes the development of MS, and allopurinol, which lowers uric acid levels, improves these features of MS in fructose (F)-fed rats. 3 We therefore hypothesized that hy-
Marked hyperuricemia is known to cause acute renal failure via intrarenal crystal deposition. However, recent studies suggest mild hyperuricemia may have vasoactive and proinflammatory effects independent of crystal formation. We therefore tested the hypothesis that mild hyperuricemia might exacerbate renal injury and dysfunction in a model of cisplatin-induced acute renal failure in the rat. Cisplatin was administered to normouricemic and hyperuricemic rats (the latter generated by administering the urate oxidase inhibitor, oxonic acid). Recombinant urate oxidase (rasburicase) was administered in a third group to assess the effect of lowering uric acid on outcomes. Other control groups include normal rats and hyperuricemic rats without cisplatin-induced injury. Cisplatin induced injury of the pars recta (S3) segment of the proximal tubule in association with a mild monocyte infiltration. Hyperuricemic rats showed significantly greater tubular injury and proliferation with significantly greater macrophage infiltration and increased expression of monocyte chemoattractant protein-1. However, renal function was not different between normouricemic and hyperuricemic rats with cisplatin injury. Treatment with rasburicase reversed the inflammatory changes and lessened tubular injury with an improvement in renal function (relative to the hyperuricemic group). No intrarenal crystals were observed in any groups. These data provide the first experimental evidence that uric acid, at concentrations that do not cause intrarenal crystal formation, may exacerbate renal injury in a model of acute renal failure. The mechanism may relate to a proinflammatory pathway involving chemokine expression with leukocyte infiltration.
Background-There is evidence that disaccharide sucrose produce a greater increase in serum fructose and triglycerides (TGs) than the effect produced by their equivalent monosaccharides, suggesting that long-term exposure to sucrose or fructose + glucose could potentially result in different effects.
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