The fructose – copper connection : Added sugars induce fatty liver and insulin resistance via copper deficiency

The Western diet may be inadequate in copper with at least 25% of adults (but up to 80% or more) in the West consuming less than the estimated average requirement.1 Importantly, copper deficiency causes many of the risk factors and pathologies of ischemic heart disease (IHD), including increased serum triglycerides and cholesterol, hypertension, increased oxidation of low-density lipoprotein (LDL) cholesterol and vascular dysfunction.2 Consumption of sucrose (table sugar, which is 50% fructose) is in turn associated with IHD with those in the highest levels of consumption of added sugars having a threefold higher risk of death because of cardiovascular disease.3 Sugar consumption is also associated with metabolic syndrome and non-alcoholic fatty liver disease4 (NAFLD); thus, feeding sugar to rats induces fatty liver.5 One of the mechanisms by which sugar leads to NAFLD may be by decreasing body copper stores and hence causing copper deficiency. This article will discuss the evidence regarding ‘the fructose–copper connection’ around NAFLD.


Introduction
The Western diet may be inadequate in copper with at least 25% of adults (but up to 80% or more) in the West consuming less than the estimated average requirement. 1Importantly, copper deficiency causes many of the risk factors and pathologies of ischemic heart disease (IHD), including increased serum triglycerides and cholesterol, hypertension, increased oxidation of low-density lipoprotein (LDL) cholesterol and vascular dysfunction. 2Consumption of sucrose (table sugar, which is 50% fructose) is in turn associated with IHD with those in the highest levels of consumption of added sugars having a threefold higher risk of death because of cardiovascular disease. 3Sugar consumption is also associated with metabolic syndrome and non-alcoholic fatty liver disease 4 (NAFLD); thus, feeding sugar to rats induces fatty liver. 5One of the mechanisms by which sugar leads to NAFLD may be by decreasing body copper stores and hence causing copper deficiency.This article will discuss the evidence regarding 'the fructose-copper connection' around NAFLD.
The prevalence of NAFLD has been increasing across the globe, and more so in developed nations with the incidence estimated to be about 20% of the United States adult population, but up to 30% of the general population in other Western countries. 6,7The causes of NAFLD are still the subject of debate, but it is associated with the metabolic syndrome and obesity.

The fructose-copper connection
The overconsumption of sugar may be one of the biggest drivers of NAFLD. 4 Several factors may be involved in sugar-driven NAFLD, including bacterial translocation from the gut to the liver and advanced glycation end products. 8However, low hepatic copper levels are also implicated in NAFLD; thus sugar consumption can lead to low copper. 9This suggests that the overconsumption of sugar may lead to NAFLD and insulin resistance via hepatic copper deficiency.
In a rat model of NAFLD, dietary sucrose and copper deficiency increased inflammation, fibrosis and lipogenesis. 9Compared to a control diet in which rats were fed with sufficient copper and 10% sucrose, either a high-sucrose diet or a low copper diet increased the hepatic expression of genes regulating inflammation and fibrosis.The low copper diet led to low serum and hepatic copper, increased lipid peroxidation and histopathology similar to that found in NAFLD.The combined low copper and high sugar diet led to all of these changes as well as hepatic insulin resistance and liver damage, but neither low copper nor high sugar caused weight gain.Low copper and high sugar promoted gene expression and physiological processes typical of NAFLD as well as non-alcoholic steatohepatitis (NASH) even without weight gain.
The fructose component of dietary sucrose, in particular, can induce copper deficiency.In rats, a diet of only 3% fructose from beverage intake -a rather modest fructose consumption that is lower than typical intake of Americans -impaired copper status and led to a significant induction of hepatic injury, iron overload and fat accumulation. 10Therefore, fructose-induced copper deficiency could be an important mechanism behind fructose-induced NAFLD.Ultra-high consumption of fructose is not necessarily required for fructose-induced fatty liver with levels lower than the average American consumption capable of inducing it in rats.
The feeding of fructose in rodents, in addition to inducing low copper status and hepatic copper deficiency, leads to a number of pathologies associated with low copper.These pathologies include iron overload, increased liver enzymes (aspartate aminotransferase or AST), increased hepatic triglycerides and increased hepatic fatty acid synthase. 11ructose feeding also causes impaired expression of the copper transporter Ctr-1 in the duodenum and reducing copper absorption in the intestine which can explain the induction of copper deficiency by fructose. 11As ceruloplasmin (the main copper-containing enzyme in the blood) is involved in oxidation of iron from ferrous to the less toxic ferric form for loading on to transferrin, lack of copper, leading to decreased ceruloplasmin, may account for the iron overload seen in fatty liver. 12Indeed, hereditary copper deficiency leads to liver iron overload. 13rturbations in hepatic iron are seen frequently in NAFLD.Patients with NAFLD have lower hepatic copper, and those with lower levels of both hepatic copper and serum copper, have higher ferritin levels (606 mg/L vs. 224 mg/L, a 2.7-fold difference), higher hepatic iron concentrations (1184 μg/g vs. 320 μg/g, 3.7-fold higher), lower concentrations of ceruloplasmin and decreased liver gene expression for ferroportin, the cellular iron exporter. 14Taken together, these results suggest that (1) copper status is linked to iron status in NAFLD; (2) a significant number of NAFLD patients are deficient in copper; and (3) low copper increases hepatic iron load by decreasing ferroportin levels and the ferroxidase function via lower ceruloplasmin which blocks liver iron export.Thus, copper deficiency may lead to hepatic iron overload causing NAFLD, NASH and hepatic insulin resistance.
High-fructose-induced copper deficiency in rats can also induce oxidative damage in the liver that does not appear to be wholly iron dependent, indicating some other cause of free-radical damage possibly via lower ceruloplasmin concentrations. 15other strategy for lowering iron levels, besides increasing copper status, is phlebotomy which can significantly treat NAFLD by improving insulin resistance. 16In Ctr-1 (copper transporter) knockout mice, defects in copper absorption lead to hepatic iron overload, along with cardiac hypertrophy and growth defects. 17A single administration of copper can rescue many of these defects.Patients with iron overload of even mild to moderate levels almost universally have some type of insulin resistance syndrome. 18Low dietary copper, whether from deficient diets or high fructose intake, may play a key role in the high prevalence of insulin resistance and NAFLD.
Although copper deficiency can lead to glucose intolerance, this phenomenon appears to occur only with simultaneous feeding of glucose or fructose, but not with starch. 19The average intake of added sugars among Americans is anywhere from 15% to 30% of calories (based on 2500 calories consumed per day). 20As noted above, even a modest (3%) intake of fructose in rats can lead to copper deficiency.Thus, the amount of sugar consumed by the average American seems to be high enough to induce copper deficiency.
Feeding of isolated cholesterol in animals can also induce copper deficiency, and in turn, deficiency of copper can induce hypercholesterolemia as well as glucose intolerance and hypertriglyceridemia. 21,22 Copper deficiency is one of the only, perhaps the only, nutritional deficiency that increases cholesterol, blood pressure and uric acid, and promotes glucose intolerance and oxidative damage, all of which are associated with atherosclerosis. 21Diets which induce copper deficiency, resemble the Western diet, which is high in sugars and fat, and low in copper.
Copper deficiency may play an important, if not the major, part in the promotion of NAFLD, insulin resistance and atherosclerosis.Known risk factors for heart disease which can be induced by copper deficiency, include elevated triglycerides, hypertension and glucose intolerance, all of which are common in the American population.High consumption of fructose leading to copper deficiency or diets inadequate in copper, could be the 'missing link' in NAFLD, insulin resistance and IHD, one that would be easily remedied by better food choices (such as shellfish, organ meats, oysters, nuts, seeds and beans) or even merely a copper supplement. 23

Conclusion
The Western diet is loaded with fructose via the consumption of added sugars.Recent estimates put sugar consumption at 15% -30% of calories consumed with 13% of the population consuming at least 25% of their calories from added 20 with a higher percentage consumption in adult females (14.5%) and young adult males (14.1%).Those figures approximate to an average consumption in the United States between 77 lbs and 152 lbs. of added sugars per person per year. 20The Western diet is also low in copper with at least 25% of people failing to ingest the estimated average requirement for copper.
The Western world is currently in the throes of an epidemic of obesity and diabetes, and along with it, fatty liver.The rest of the world is catching up in incidence of these diseases.
Fructose, via the induction of copper deficiency, could be driving these conditions, along with the well-known and long-standing epidemic of heart disease.The evidence presented here shows that high sugar consumption with resultant copper deficiency could well be a very important factor in these diseases of civilisation.More research is needed to (1) to delineate the degree to which the average person is copper sufficient or insufficient; (2) study the degree to which groups of people with or without these diseases differ in levels of body copper stores and dietary copper intake; (3) study trials of copper supplementation and/or prospective studies of copper status and ensuing pathologies; and (4) explain mechanisms of fructose-induced copper deficiency and iron overload.