Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Am J Physiol Heart Circ Physiol 293: H1853–H1860, 2007. First published July 6, 2007; doi:10.1152/ajpheart.00544.2007. Deleterious effects of sugar and protective effects of starch on cardiac remodeling, contractile dysfunction, and mortality in response to pressure overload David J. Chess,1 Biao Lei,3 Brian D. Hoit,2 Agnes M. Azimzadeh,4 and William C. Stanley1,3 Departments of 1Physiology and Biophysics and 2Medicine, School of Medicine, Case Western Reserve University, Cleveland, Ohio; and Division of Cardiology, Departments of 3Medicine and 4Surgery, University of Maryland, Baltimore, Maryland Submitted 9 May 2007; accepted in final form 3 July 2007 CHRONIC ARTERIAL PRESSURE OVERLOAD is a major cause of left ventricular (LV) hypertrophy (LVH), which frequently progresses to heart failure (HF). Even with modern pharmacological treatment, many patients with hypertension still develop LVH and HF (44). Thus, novel therapies are needed to prevent LVH and/or the development of HF, especially those that act independently of the neurohormonal axis. Nutritional approaches are particularly attractive because they could work additively with medicinal therapies while not exerting negative hemodynamic effects (37). While a high-carbohydrate/low-fat diet is recommended for the prevention of heart disease (21), a recent epidemiological study (12) found a twofold increase in the risk of coronary heart disease in women consuming a diet of high glycemic index (i.e., one containing foods rich in sugars and rapidly digested polysaccharides) compared with a diet low in sugar. Diets with a high glycemic load influence the development of obesity and metabolic syndrome, which have become an epidemic in this country and are positively associated with cardiovascular disease risk (33). The occurrence of such risk factors is reduced by diets of a lower glycemic load or those rich in complex carbohydrates (23, 36). Thus, current guidelines suggest that dietary carbohydrate should be comprised mainly of complex carbohydrates (starches) rather than sugars (21). High carbohydrate composition may be associated with LVH due to activation of the insulin signaling pathway in the heart (4, 40). Clinical studies (34, 39, 43) have found that hypertensive patients with a high plasma insulin in the fed state have a greater occurrence of LVH, suggesting that elevated insulin may trigger pathological cardiac growth when the heart is subjected to chronic pressure overload. Recently, we (38) observed that feeding a high-carbohydrate diet comprised mainly of fructose to hypertensive Dahl salt-sensitive rats impaired LV function and increased mortality by 85% over a 13-wk period compared with a standard laboratory chow. Studies (4, 40) in transgenic mice have also suggested that the activation of insulin signaling can lead to LVH and cardiac dysfunction. The main effector of insulin signaling is the serine/threonine kinase Akt, whose overexpression results in increased protein synthesis (40), inhibited protein breakdown (27, 41), and subsequently massive LVH (22). Insulin also affects the activity of AMP-activated protein kinase (AMPK), which upregulates glucose and fatty acid utilization during periods of low energy (1, 19). The effects of diet on Akt and AMPK expression and activation in mediating structural and metabolic remodeling of the heart during chronic pressure overload are unclear. Nuclear receptor signaling is also affected by dietary macronutrients. A recent study (10) in transgenic mouse models of metabolic syndrome has suggested that mitochondrial biogenesis is stimulated by increased lipid availability and activation of peroxisome proliferator-activated receptor-␣ (PPAR-␣) and its coactivators. PPAR-␣, which is suppressed in severe LVH and HF, is activated by long-chain fatty acids and regulates the expression of proteins involved in fatty acid metabolism (42). Dietary fat and carbohydrate intake alters the development of LVH and the progression toward HF (30, 38); thus, sugar consumption may accelerate the deactivation of PPAR-␣, resulting in impaired cardiac fatty acid metabolism and mitochondrial function under conditions of pressure overload. Address for reprint requests and other correspondence: W. C. Stanley, Div. of Cardiology, Dept. of Medicine, Univ. of Maryland, 20 Penn St., HSF-II, Rm. S022, Baltimore, MD 21201 (e-mail: [email protected]). The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. glycemic index; ejection fraction; heart failure http://www.ajpheart.org 0363-6135/07 $8.00 Copyright © 2007 the American Physiological Society H1853 Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 Chess DJ, Lei B, Hoit BD, Azimzadeh AM, Stanley WC. Deleterious effects of sugar and protective effects of starch on cardiac remodeling, contractile dysfunction, and mortality in response to pressure overload. Am J Physiol Heart Circ Physiol 293: H1853–H1860, 2007. First published July 6, 2007; doi:10.1152/ajpheart.00544.2007.—Little is known about the effects of the composition of dietary carbohydrate on the development of left ventricular (LV) hypertrophy (LVH) and heart failure (HF) under conditions of pressure overload. The objective of this study was to determine the effect of carbohydrate composition on LVH, LV function, and mortality in a mouse model of chronic pressure overload. Male C57BL/6J mice of 6 wk of age (n ⫽ 14 –16 mice/group) underwent transverse aortic constriction (TAC) or sham surgery and were fed either standard chow (STD; 32% corn starch, 35% sucrose, 3% maltodextrin, and 10% fat expressed as a percent of the total energy), high-starch chow (58% corn starch, 12% maltodextrin, and 10% fat), or high-fructose chow (9% corn starch, 61% fructose, and 10% fat). After 16 wk of treatment, mice with TAC fed the STD or high-fructose diets exhibited increased LV mass, larger end-diastolic and end-systolic diameters, and decreased ejection fraction compared with sham. The high-starch diet, in contrast, prevented changes in LV dimensions and contractile function. Cardiac mRNA for myosin heavy chain- was increased dramatically in the fructose-fed banded animals, as was mortality (54% compared with 8% and 29% in the starch and STD banded groups, respectively). In conclusion, a diet high in simple sugar was deleterious, resulting in the highest mortality and expression of molecular markers of cardiac dysfunction in TAC animals compared with sham, whereas a high-starch diet blunted mortality, increases in cardiac mass, and contractile dysfunction. H1854 CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY METHODS Induction of pressure overload in C57BL/6J mice. Transverse aortic constriction (TAC) was performed on male C57BL/6J mice at 6 wk of age as previously described (13) using a 26-gauge needle to induce clinically relevant hypertrophy. The sham procedure was identical without aortic ligation. This study was conducted according to the National Institutes of Health Guidelines for the Care and Use of Laboratory Animals (NIH Pub. No. 85-23) and was approved by the Institutional Animal Care and Use Committee of Case Western Reserve University. Animals were maintained on a 12:12-h light-dark cycle. Diets. All diets were custom formulated by Research Diets (New Brunswick, NJ). The macronutrient composition of the diets is shown in Table 1. Animals were fed institutionally available laboratory chow (Harlan Teklad 2014, Global 14% Protein Rodent Maintenance Diet) for 1 wk. Following surgery, animals were randomly assigned to either the high-starch (starch), standard (STD), or high-fructose (fructose) diet for the remainder of the study. Echocardiography. LV dimensions and function were measured at 5 and 16 wk postsurgery as previously described (28, 29) using isoflurane anesthesia. Relative wall thickness (RWT) was approximated using the following formula: RWT ⫽ (LVPWTd ⫹ LVSWTd)/ (LVEDD), where LVPWTd is LV posterior wall thickness at end diastole, LVSWTd is LV septal wall thickness at end diastole, and LVEDD is LV end-diastolic diameter. The myocardial performance index (MPI), a reflection of LV systolic and diastolic function whose magnitude is inversely related to myocardial performance, was calculated using the following formula: MPI ⫽ (IVCT ⫹ IVRT)/(ET), where IVCT and IVRT are isovolumic contraction and relaxation times, respectively, and ET is ejection time. The ejection fraction (EF) was calculated using the following equation: EF ⫽ [(LVEDV ⫺ LVESV)/(LVEDV)] ⫻ 100, where LVEDV and LVESV are LV end-diastolic and end-systolic volumes, respectively. Terminal surgery. Terminal surgeries were performed on fed mice between 3 and 6 h from the initiation of the dark phase (18:00) on the light-dark cycle. After 16 wk of treatment, mice were weighed and anesthetized with 1.5–2.0% isoflurane. The thoracic cavity was opened by cutting from the xiphoid cartilage around the ventral portion of the ribs. The heart was removed, weighed, freeze clamped, and stored at ⫺80°C. Pooled blood was collected from the thoracic cavity after heart excision for the analysis of plasma and serum metabolites. Metabolic measurements. Plasma glucose, insulin, free fatty acids, and triglycerides were determined using commercially available kits. Serum leptin and total plasma adiponectin (individual adiponectin isoforms were not assessed) were measured with colorimetric enzyme-linked immunosorbent assays. MCAD and citrate synthase (CS) activities were analyzed from tissue homogenates as previously described (31). mRNA expression analysis. Powdered heart tissue was disrupted and homogenized by being shaken in solution with 5-mm stainless steel beads for 3 min at 30 s⫺1 (Mixermill 300, Qiagen) followed by RNA isolation (RNeasy Mini Kit, Qiagen). RNA samples were eluted in 50 l of nuclease-free water and stored at ⫺80°C. For cDNA synthesis, RNA (1 g) was mixed with 2 L oligo(dT)16 (Applied Biosystems) and 0.5 l random primers (Invitrogen) and brought to 15 l of total volume. The sample/primer mix was heated to 70°C for 10 min and then placed immediately on ice for 2 min followed by the addition of the RT reaction mix containing 5⫻ buffer (5 l) and 0.1 M DTT (2.5 l, Superscript II RT, Invitrogen), 10 mM dNTP (1.25 l, Invitrogen), and RNase inhibitor (0.25 l, Applied Biosystems). The reaction mix was incubated for 2 min at 42°C, 1 l reverse transcriptase was added, and the incubation was continued at 42°C for 1 h. The reaction mix was then incubated at 70°C for 10 min and placed on ice for 2 min. The resulting cDNA samples were stored at ⫺20°C. Quantitative RT-PCR (qRT-PCR) was performed using an ABI 7900 and the following protocol: 2 min at 50°C, 10 min at 95°C, and 40 cycles at 95°C for 15 s and 1 min at 60°C. Each reaction was 25 l, consisting of 1.0 l cDNA sample, 1.25 l TaqMan Gene Expression Assay, 12.5 l of 2⫻ TaqMan PCR master mix, and 10.25 l nuclease-free water. Expressions of atrial natriuretic peptide, myosin heavy chain (MHC)-␣, MHC-, MCAD, CS, PPAR-␣, carnitine palmitoyl transferase I, pyruvate dehydrogenase kinase 4, uncoupling protein 3, and peptidylprolyl isomerase A (internal control) were determined by qRT-PCR using Assays-On-Demand probes (Applied Biosystems). mRNA concentrations were normalized to the fold increase relative to the STD sham group. Western blot analysis. Protein was extracted from frozen cardiac tissue, separated by electrophoresis in 10% SDS-PAGE gels, transferred onto nitrocellulose membranes, and incubated with specific antibodies to either phosphorylated Akt (Ser473) or phosphorylated AMPK (Thr172 of the ␣-subunit) (all at 1:1,000, from Cell Signaling Technology). Fluorescence-conjugated secondary antibodies (IRDye 680/800, 1:5,000, LI-COR Bioscience) were used for incubation before the membranes were scanned and analyzed with the Odyssey infrared imaging system (LI-COR Bioscience). Membranes were then stripped (Pierce Restore stripping buffer) and reprobed for total Akt and AMPK (1:1,000, Cell Signaling). Statistical analysis. All analysis was performed with the investigator(s) blinded. Two-way ANOVA with Bonferroni post hoc adjustment was used to compare all dietary groups with and without aortic constriction. Differences in mortality were assessed by a Kaplan- Table 1. Macronutrient composition of the diets used in this study Fat Carbohydrate Protein Diet Soy Oil Cocoa Butter Cornstarch Fructose Sucrose Maltodextrin Casein Total STD Starch Fructose 3 3 3 7 7 7 32 58 9 0 0 61 35 0 0 3 12 0 20 20 20 100 100 100 Values are the contributions of fats, carbohydrates, and proteins to the total energy content of the diet (% of total). Diets were matched for vitamin and mineral content and were all on a low-sodium background (⬃0.26% by mass). STD, standard diet; starch, high-starch diet; fructose, high-fructose diet. AJP-Heart Circ Physiol • VOL 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 This study evaluated the effect of carbohydrate composition on the development of structural, functional, and metabolic abnormalities in response to pressure overload. We hypothesized that a high-sugar diet would exacerbate cardiac remodeling and dysfunction and increase mortality in mice with aortic constriction. A top-down approach was taken, with the effects of carbohydrate composition assessed by mortality, echocardiographic measurements of LV chamber dimensions and function, and quantification of hormones and metabolites in blood, activity of key metabolic enzymes, gene expression, and hypertrophic signaling pathways. The activation of PPAR-␣ was assessed through measurements of transcript levels of established PPAR-␣ target genes and the activity of the fatty acid -oxidation enzyme medium-chain acyl-CoA dehydrogenase (MCAD). H1855 CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY Fig. 1. Percent survival in sham (A) and transverse aortic constriction (TAC; B) mice displayed graphically over the 16-wk duration of the study. Starch, high-starch diet; fructose, high-fructose diet; STD, standard diet. *P ⬍ 0.05 compared with TAC mice on the starch diet. Each group contained 14 –16 animals at the onset of dietary treatment. Meier survival curve with 2-analysis (SPSS Base 15.0, SPSS, Chicago, IL). All data are presented as means ⫾ SE. P ⬍ 0.05 was accepted as statistically significant. RESULTS Survival. All sham-operated mice on the STD and starch diets survived the 16-wk duration of the study. Mortality was observed in mice with TAC on STD and starch diets (29% and 8%, respectively; Fig. 1B). The fructose diet had the most obvious effect on survival, inducing mortality rates in both sham (21%; Fig. 1A) and TAC (54%; Fig. 1B) mice. The mortality observed in TAC mice on the fructose diet was significantly greater than starch diet-fed TAC mice. However, TAC-induced mortality was not different between fructose diet- and STD diet-fed mice compared with sham mice (Fig. 1, A and B). Body and heart mass. No significant differences in body mass were observed in either sham or TAC animals fed the three diets (Table 2). Average daily food consumption was also not different among groups (data not shown). TAC increased heart weight (normalized to tibia length) by 38.7% in STD diet-fed mice and 25.3% in fructose diet-fed mice compared with sham animals on the same diets (Fig. 2). The starch diet completely prevented the increase in heart weight in mice with TAC. TAC led to a significant reduction in epididymal fat pad mass in fructose diet-fed mice compared with mice on the starch diet (Table 2). LV dimensions and performance. There were no differences in echocardiographic measurements among dietary and/or surgical groups at 5 wk (data not shown). After 16 wk of treatment, LVEDD and LVESD were increased significantly by TAC in the fructose diet-fed group compared with its respective sham group, but there were no differences between TAC and sham animals in the STD or starch diet groups (Fig. 3, A and B). TAC reduced EF (Fig. 3C) in both STD dietand fructose diet-fed mice compared with sham mice; however, there was no difference between sham and TAC mice in the starch diet group. The MPI, whose magnitude is inversely related to myocardial performance, was increased significantly in TAC animals on the STD and fructose diets compared with their respective shams; however, there were no differences in MPI between sham and TAC animals on the starch diet (Fig. 3D). Table 2. Body measurements taken at terminal procedure following 16 wk of dietary treatment Starch STD Fructose Measurements Sham (n ⫽ 16) TAC (n ⫽ 14) Sham (n ⫽ 14) TAC (n ⫽ 11) Sham (n ⫽ 10) TAC (n ⫽ 8) Body weight, g Heart weight, mg Tibia length, mm Epididymal fat, mg 28⫾1 153.4⫾3.7 17.05⫾0.20 518.0⫾36.6 28⫾1 160.5⫾12.9 16.97⫾0.14 613.1⫾63.1 28⫾1 154.3⫾5.5 16.77⫾0.21 541.7⫾40.6 27⫾1 214.0⫾21.8* 17.11⫾0.13 412.7⫾71.9 27⫾1 147.2⫾4.7 17.12⫾0.29 467.1⫾24.4 26⫾1 184.4⫾21.6* 17.14⫾0.14 383.0⫾27.2*† Values are means ⫾ SE; n, no. of animals. TAC, transverse aortic constriction. *P ⬍ 0.05 vs. sham animals on the same diet; †P ⬍ 0.05 vs. TAC animals on the starch diet. AJP-Heart Circ Physiol • VOL 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 Fig. 2. Terminal heart weight (HW)-to-tibia length ratios of sham (n ⫽ 10 –16 mice/group) and TAC (n ⫽ 8 –14 mice/group) animals. Data are means ⫾ SE. *P ⬍ 0.05 compared with sham animals on the same diet. H1856 CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY Metabolic parameters. Plasma glucose was unaffected by TAC or dietary treatment. No differences were observed in plasma free fatty acid concentrations among all groups. Plasma triglycerides, however, were increased significantly in both TAC and sham mice on the starch diet compared with all other TAC and sham groups (Table 3). Plasma insulin was similar in sham and TAC animals fed the STD and starch diets but was significantly increased in the fructose-fed TAC group compared with its respective sham (Table 3). Total adiponectin levels were unchanged with dietary manipulation in either sham or TAC mice. Serum leptin was significantly elevated in TAC animals compared with sham animals in the starch diet-fed groups. Fructose feeding lowered the activity of MCAD in TAC animals relative to sham animals (Fig. 4A). CS activity, a marker of mitochondrial density and oxidative capacity, was reduced in TAC animals consuming STD and fructose diets compared with their respective sham groups (Fig. 4B). The ratio of MCAD activity to CS activity was unaffected by TAC or diet (data not shown), suggesting there was not a preferential downregulation of fatty acid -oxidation. mRNA expression. There was a trend toward increases in atrial natriuretic factor mRNA in animals with TAC (Table 4). TAC caused a switch in MHC isoform from ␣ to , an effect that was enhanced dramatically by fructose diet feeding (Fig. 5) due to a 17-fold increase in MHC- (Table 4). TAC also reduced the mRNA expression of MCAD and PPAR-␣. Within the TAC groups, PPAR-␣ expression was significantly decreased with the fructose diet compared with the starch diet (Table 4). Western blot analysis. There were no significant differences in total Akt protein levels or the ratio of phosphorylated Akt (Ser473) to total Akt between any of the treatment groups (Table 5). Similarly, there were no significant differences in total AMPK protein levels or the ratio of phosphorylated AMPK (Thr172 of the ␣-subunit) to total AMPK (Table 5). DISCUSSION The primary findings from this study were that compared with a complex carbohydrate diet, a diet high in sugar increased the mortality and expression of molecular markers of Table 3. Metabolite and hormone concentrations in plasma or serum in fed animals after 16 wk of treatment Starch STD Fructose Metabolite or Hormone Sham (n ⫽ 10) TAC (n ⫽ 8) Sham (n ⫽ 9) TAC (n ⫽ 8) Sham (n ⫽ 8) TAC (n ⫽ 7) Plasma glucose, mM Plasma free fatty acids, mM Plasma triglycerides, mg/ml Plasma insulin, nM Plasma adiponectin, g/ml Serum leptin, ng/ml 9.15⫾0.28 0.44⫾0.03 0.52⫾0.06a 0.93⫾0.26 2.02⫾0.17 1.81⫾0.23 8.48⫾0.23 0.51⫾0.06 0.65⫾0.12b 0.81⫾0.14 2.86⫾0.11c 3.12⫾0.34c,e 8.80⫾0.61 0.38⫾0.05 0.36⫾0.04 0.59⫾0.07 2.09⫾0.26 2.13⫾0.30 8.16⫾0.32 0.48⫾0.04 0.33⫾0.04 0.70⫾0.15 2.48⫾0.24 2.34⫾0.27 8.61⫾0.30 0.53⫾0.13 0.31⫾0.04 0.64⫾0.18 2.60⫾0.52 1.71⫾0.34 9.34⫾0.56 0.41⫾0.03 0.33⫾0.09 1.68⫾0.37c,d 2.05⫾0.20 1.84⫾0.20 c Values are means ⫾ SE; n, no. of animals. aP ⬍ 0.05 vs. sham animals on STD and fructose diets; bP ⬍ 0.05 vs. TAC animals on STD and fructose diets; P ⬍ 0.05 vs. sham animals on the same diet; dP ⬍ 0.05 vs. TAC animals on STD and starch diets; eP ⬍ 0.05 vs. TAC animals on the fructose diet. AJP-Heart Circ Physiol • VOL 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 Fig. 3. Echocardiographic parameters. Enddiastolic diameter (EDD; A), end-systolic diameter (ESD; B), ejection fraction (EF; C), and myocardial performance index (MPI; D) were measured in the hearts of sham and TAC animals following 16 wk of treatment. Open bars represent sham animals; closed bars represent TAC animals. The numbers of animals used for all echocardiographic measurements are shown in A. Data are means ⫾ SE. *P ⬍ 0.05 compared with sham animals on the same diet. H1857 CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY LVH and HF under conditions of pressure overload. The expression of fetal genes, LV contractile dysfunction, and mortality in TAC animals increased as a function of the percentage of calories derived from sugar (Figs. 1–5). These Table 4. mRNA expression of cardiac genes determined by quantitative RT-PCR Starch STD Fructose Gene Product Sham (n ⫽ 10) TAC (n ⫽ 8) Sham (n ⫽ 9) TAC (n ⫽ 8) Sham (n ⫽ 8) TAC (n ⫽ 7) P Values (TAC vs. sham) Nppa Myh6 Myh7 Acadm Cs Ppara Cpt1b Pdk4 Ucp3 ANF MHC-␣ MHC- MCAD CS PPAR-␣ CPT-I PDK4 UCP3 0.65⫾0.15 1.08⫾0.13 0.91⫾0.14 1.06⫾0.05 1.23⫾0.17 1.18⫾0.14 1.06⫾0.13 0.72⫾0.13 1.21⫾0.33 1.01⫾0.23 1.00⫾0.05 1.60⫾0.18* 0.86⫾0.07 0.97⫾0.10 1.00⫾0.11 0.87⫾0.05 0.67⫾0.11 1.03⫾0.19 1.00⫾0.23 1.00⫾0.09 1.00⫾0.17 1.00⫾0.07 1.00⫾0.13 1.00⫾0.13 1.00⫾0.08 1.00⫾0.20 1.00⫾0.17 1.19⫾0.17 0.91⫾0.18 2.72⫾0.38* 0.90⫾0.09 0.87⫾0.13 0.78⫾0.14 0.86⫾0.07 0.84⫾0.14 1.05⫾0.23 1.27⫾0.31 1.03⫾0.11 1.55⫾0.28 0.93⫾0.09 1.04⫾0.15 0.94⫾0.13 1.00⫾0.09 0.78⫾0.13 1.29⫾0.48 1.50⫾0.27 0.76⫾0.16 16.59⫾3.17*† 0.75⫾0.07 0.78⫾0.14 0.64⫾0.13‡ 0.91⫾0.10 0.46⫾0.12 1.15⫾0.41 0.069 NS ⬍0.001 0.015 NS 0.035 NS NS NS Data are presented as means ⫾ SE of fold changes in gene expression relative to the STD diet-fed sham group; n, no. of animals. ANF, atrial natriuretic factor; MHC, myosin heavy chain; MCAD, medium-chain acyl-CoA dehydrogenase; CS, citrate synthase; PPAR-␣, peroxisome proliferator-activated receptor-␣; CPT-I, carnitine palmitoyl transferase-I; PDK4, pyruvate dehydrogenase kinase 4; UCP3, uncoupling protein 3; NS, not significant. *P ⬍ 0.05 vs. sham animals on the same diet; †P ⬍ 0.05 vs. TAC animals on STD and starch diets; ‡P ⬍ 0.05 vs. TAC animals on the starch diet. AJP-Heart Circ Physiol • VOL 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 Fig. 4. Activities of medium-chain acyl-CoA dehydrogenase (MCAD; A) and citrate synthase (CS; B) in cardiac tissue measured spectrophotometrically. Data are means ⫾ SE. *P ⬍ 0.05 compared with sham animals on the same diet. †Values of the fructose TAC group were significantly lower than those of the starch TAC group (P ⬍ 0.05). findings suggest that dietary sugar composition can promote cardiac remodeling and contractile dysfunction in the presence of chronic pressure overload. Fructose diet feeding in the TAC mice also decreased the activities of MCAD and CS, marker enzymes for myocardial fatty acid oxidation capacity and citric acid cycle flux, respectively. These decreases in enzyme activity occurred despite no alterations in the mRNA for either MCAD or CS (Table 4). These findings differ from our previous observations showing that MCAD activity and protein expression remained unchanged despite reductions in MCAD gene expression (24) and contrasts with evidence of HF-induced downregulation of fatty acid oxidation genes (8, 32). These conflicting results reinforce the notion that there are frequent disconnections between mRNA and protein levels during LVH and HF (24, 42). The precise mechanism for increased mortality in the fructose diet-fed TAC group is not known. Previous studies (4, 14, 40) have suggested that enhanced activation of the Akt-insulin pathway could contribute to LVH and contractile dysfunction in transgenic animals and isolated cardiomyocytes. In this study, however, there was no increase in Akt activation in TAC animals on the fructose diet despite a significant elevation in plasma insulin. This discrepancy may be attributed to eating patterns of the mice prior to terminal studies, as it has been shown that Akt activation is highly dependent on nutritional status (40). There were also no changes observed in the expression and activation of AMPK. To our knowledge, only two studies have measured the effects of cardiac hypertrophy on the activation and expression of AMPK. A study (18) in juvenile pigs with volume overload-induced LVH showed an ⬃30% decrease in AMPK activity in freeze-clamped myocardial tissue. In contrast, ex vivo perfused hearts from rats subjected to 17–19 wk of ascending aortic banding exhibited an approximately threefold increase in AMPK activity (45). Thus, at this point, the role of this protein in the development of LVH remain unclear. The expression of PPAR-␣ mRNA was reduced in the TAC mice fed the fructose diet; however, the expression of PPAR-␣-regulated genes (such as MCAD) was unaffected by diet among TAC groups. Nonetheless, the activity of MCAD was suppressed in TAC mice on the fructose diet (Fig. 4). CS activity was also reduced in the fructose diet group, suggesting that fructose diet feeding in the setting of pressure overload H1858 CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY exacerbated the impairment in mitochondrial oxidative metabolism. The effects of fructose diet feeding may be mediated by the development of metabolic syndrome (insulin resistance, hyperglycemia, dyslipidemia, hypertension, and/or obesity). The consumption of dietary fructose, particularly in more developed countries in which many foods are enriched with highfructose corn syrup, has been suggested to contribute to the development of obesity and its corresponding metabolic abnormalities (3, 5, 11, 16, 25). Fructose diet feeding is a well-established model of metabolic syndrome, as it leads to hypertension, hypertriglyceridemia, and insulin resistance in rats (15). Mild insulin resistance was suggested in fructose diet-fed TAC animals as they displayed significantly higher plasma insulin compared with starch diet- and STD diet-fed TAC animals and also exhibited the highest glycemia (Table 3). Secondary to this modest insulin resistance was impaired Akt activation, which has been shown previously (9). It is also possible that the fructose diet increased blood pressure in TAC mice; thus, a limitation of the present study is the lack of blood pressure data. Studies (20, 26) have shown mild decreases in arterial pressure in C57BL/6J mice using the noninvasive tail-cuff method following 11 wk of TAC. Terminal measurements of ventricular pressure could have been performed through LV catheterization, but the additional stress of anesthesia and arterial catheterization likely would have altered cardiac signaling pathways (e.g., Akt and AMPK acti- Table 5. Western blot densitometry of Akt, phospho-Akt (Ser473), AMPK, and phospho-AMPK (Thr172) in the heart Starch STD Fructose Protein Sham (n ⫽ 8) TAC (n ⫽ 7) Sham (n ⫽ 8) TAC (n ⫽ 7) Sham (n ⫽ 7) TAC (n ⫽ 6) Phospho-Akt Total Akt Phospho-Akt/total Akt Phospho-AMPK Total AMPK Phospho-AMPK/total AMPK 0.89⫾0.09 0.97⫾0.09 0.92⫾0.08 0.86⫾0.06 1.10⫾0.18 0.84⫾0.11 0.99⫾0.11 0.89⫾0.06 1.10⫾0.06 0.95⫾0.04 1.04⫾0.09 0.92⫾0.08 1.00⫾0.08 1.00⫾0.06 1.00⫾0.07 1.00⫾0.07 1.00⫾0.06 1.00⫾0.08 0.83⫾0.06 0.99⫾0.06 0.86⫾0.08 0.87⫾0.06 0.99⫾0.09 0.89⫾0.06 0.88⫾0.10 1.09⫾0.12 0.87⫾0.09 0.88⫾0.03 1.06⫾0.07 0.83⫾0.06 0.78⫾0.03 1.11⫾0.12 0.76⫾0.09 0.93⫾0.02 1.17⫾0.10 0.81⫾0.07 Values are means ⫾ SE. Data are presented as fold changes in protein expression relative to the STD diet-fed sham group (in arbitrary units). AMPK, AMP-activated protein kinase. AJP-Heart Circ Physiol • VOL 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 Fig. 5. Ratio of myosin heavy chain (MHC)- to MHC-␣ mRNA expression relative to the STD sham group (dashed line) as determined by quantitative RT-PCR. Data are means ⫾ SE. *P ⬍ 0.05 compared with sham animals on the same diet; †P ⬍ 0.05 compared with TAC animals on the STD and starch diets. vation). Recently, Joho et al. (17) demonstrated that LV pressure and volume can be measured in conscious, unrestrained mice. Thus, future studies should investigate the effects of diet on arterial and LV pressure in sham and TAC animals. The mechanism for the increased mortality in fructose dietfed sham animals is unclear. No evidence of cardiac-related death was found based on EF (Fig. 3c) or the expression of atrial naturietic factor or MHC- (Table 4). A possible explanation for the mortality seen in the fructose diet-fed sham group is renal damage. It has recently been shown in rats that 60% fructose consumption over 8 wk was associated with kidney hypertrophy, glomerular hypertension, cortical vasoconstriction, and a decreased glomerular filtration rate (35). In the present study, 61% fructose diet feeding was maintained for 16 wk, possibly inducing irreversible renal damage and subsequent death due to renal failure. Future studies involving chronic fructose diet feeding should assess structural and functional aspects of the kidney to provide evidence for this hypothesis. An important finding in this study was the cardioprotective effects of a high-starch diet during chronic pressure overload. Cornstarch, the primary source of carbohydrate in the starch diet used in this study, contains mostly amylopectin. Having a branched-chain configuration, amylopectin is more susceptible to degradation by ␣-glucosidases compared with straight-chain amylose, suggesting a relatively high glycemic index for the starch diet and theoretically greater cardiac growth. However, TAC animals consuming the starch diet exhibited no increase in heart mass or contractile dysfunction compared with sham animals. The beneficial effects of high-starch diet feeding may be related to overall myocardial oxidative capacity, as the activities of MCAD and CS were maintained in starch diet-fed TAC mice compared with fructose diet-fed TAC mice (Fig. 4). Further studies are needed to determine how dietary manipulation during pressure overload affects substrate preference and the hypertrophic response. The blunting of cardiac hypertrophy and contractile dysfunction with high-starch diet feeding may also be species dependent. A concurrent feeding study in our laboratory involving the rat abdominal aortic constriction model of pressure overload found similar increases cardiac mass, LVESV, and LVEDV in animals fed either a high-sugar or high-starch diet (M. K. Duda, K. M. O’Shea, and W. C. Stanley, unpublished data). However, compared with a high-starch diet, feeding a high-sugar diet to hypertensive Dahl salt-sensitive rats decreased EF and increased mortality (38), consistent with the findings of the present investigation. Taken together, those CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY ACKNOWLEDGMENTS We acknowledge Karen O’Shea, Kristen King, and Celvie Yuan for the help with the terminal surgeries, Dr. Willem Kop for the assistance in the survival analyses, and Dr. Brian Barrows for the technical support with the quantitative RT-PCR. We thank Dr. Ken Walsh and Dr. Kaori Sato at Boston University for teaching us the TAC procedure. GRANTS This work was supported by National Heart, Lung, and Blood Institute Grant HL-074237. REFERENCES 1. Abel ED, Kaulbach HC, Tian R, Hopkins JC, Duffy J, Doetschman T, Minnemann T, Boers ME, Hadro E, Oberste-Berghaus C, Quist W, Lowell BB, Ingwall JS, Kahn BB. Cardiac hypertrophy with preserved contractile function after selective deletion of GLUT4 from the heart. J Clin Invest 104: 1703–1714, 1999. 2. Anker SD, von Haehling S. Inflammatory mediators in chronic heart failure: an overview. Heart 90: 464 – 470, 2004. 3. Basciano H, Federico L, Adeli K. Fructose, insulin resistance, and metabolic dyslipidemia. Nutr Metab (Lond) 2: 5, 2005. 4. Belke DD, Betuing S, Tuttle MJ, Graveleau C, Young ME, Pham M, Zhang D, Cooksey RC, McClain DA, Litwin SE, Taegtmeyer H, Severson D, Kahn CR, Abel ED. Insulin signaling coordinately regulates cardiac size, metabolism, and contractile protein isoform expression. J Clin Invest 109: 629 – 639, 2002. 5. Bray GA. The epidemic of obesity and changes in food intake: the fluoride hypothesis. Physiol Behav 82: 115–121, 2004. AJP-Heart Circ Physiol • VOL 6. Busserolles J, Gueux E, Rock E, Mazur A, Rayssiguier Y. High fructose feeding of magnesium deficient rats is associated with increased plasma triglyceride concentration and increased oxidative stress. Magnes Res 16: 7–12, 2003. 7. Busserolles J, Rock E, Gueux E, Mazur A, Grolier P, Rayssiguier Y. Short-term consumption of a high-sucrose diet has a pro-oxidant effect in rats. Br J Nutr 87: 337–342, 2002. 8. de Brouwer KF, Degens H, Aartsen WM, Lindhout M, Bitsch NJ, Gilde AJ, Willemsen PH, Janssen BJ, van der Vusse GJ, van Bilsen M. Specific and sustained down-regulation of genes involved in fatty acid metabolism is not a hallmark of progression to cardiac failure in mice. J Mol Cell Cardiol 40: 838 – 845, 2006. 9. Deng JY, Huang JP, Lu LS, Hung LM. Impairment of cardiac insulin signaling and myocardial contractile performance in high cholesterolfructose fed rats. Am J Physiol Heart Circ Physiol. First published March 30, 2007; doi:10.1152/ajpheart.01002.2006. 10. Duncan JG, Fong JL, Medeiros DM, Finck BN, Kelly DP. Insulinresistant heart exhibits a mitochondrial biogenic response driven by the peroxisome proliferator-activated receptor-alpha/PGC-1alpha gene regulatory pathway. Circulation 115: 909 –917, 2007. 11. Gaby AR. Adverse effects of dietary fructose. Altern Med Rev 10: 294 –306, 2005. 12. Halton TL, Willett WC, Liu S, Manson JE, Albert CM, Rexrode K, Hu FB. Low-carbohydrate-diet score and the risk of coronary heart disease in women. N Engl J Med 355: 1991–2002, 2006. 13. Hu P, Zhang D, Swenson L, Chakrabarti G, Abel ED, Litwin SE. Minimally invasive aortic banding in mice: effects of altered cardiomyocyte insulin signaling during pressure overload. Am J Physiol Heart Circ Physiol 285: H1261–H1269, 2003. 14. Hunter JJ, Chien KR. Signaling pathways for cardiac hypertrophy and failure. N Engl J Med 341: 1276 –1283, 1999. 15. Hwang IS, Ho H, Hoffman BB, Reaven GM. Fructose-induced insulin resistance and hypertension in rats. Hypertension 10: 512–516, 1987. 16. Jacobson MF. High-fructose corn syrup and the obesity epidemic. Am J Clin Nutr 80: 1081–1082, 2004. 17. Joho S, Ishizaka S, Sievers R, Foster E, Simpson PC, Grossman W. Left ventricular pressure-volume relationship in conscious mice. Am J Physiol Heart Circ Physiol 292: H369 –H377, 2007. 18. Kantor PF, Robertson MA, Coe JY, Lopaschuk GD. Volume overload hypertrophy of the newborn heart slows the maturation of enzymes involved in the regulation of fatty acid metabolism. J Am Coll Cardiol 33: 1724 –1734, 1999. 19. Kudo N, Gillespie JG, Kung L, Witters LA, Schulz R, Clanachan AS, Lopaschuk GD. Characterization of 5⬘AMP-activated protein kinase activity in the heart and its role in inhibiting acetyl-CoA carboxylase during reperfusion following ischemia. Biochim Biophys Acta 1301: 67– 75, 1996. 20. Liao Y, Ishikura F, Beppu S, Asakura M, Takashima S, Asanuma H, Sanada S, Kim J, Ogita H, Kuzuya T, Node K, Kitakaze M, Hori M. Echocardiographic assessment of LV hypertrophy and function in aorticbanded mice: necropsy validation. Am J Physiol Heart Circ Physiol 282: H1703–H1708, 2002. 21. Lichtenstein AH, Appel LJ, Brands M, Carnethon M, Daniels S, Franch HA, Franklin B, Kris-Etherton P, Harris WS, Howard B, Karanja N, Lefevre M, Rudel L, Sacks F, Van Horn L, Winston M, Wylie-Rosett J. Diet and lifestyle recommendations revision 2006: a scientific statement from the American Heart Association Nutrition Committee. Circulation 114: 82–96, 2006. 22. Matsui T, Li L, Wu JC, Cook SA, Nagoshi T, Picard MH, Liao R, Rosenzweig A. Phenotypic spectrum caused by transgenic overexpression of activated Akt in the heart. J Biol Chem 277: 22896 –22901, 2002. 23. McKeown NM, Meigs JB, Liu S, Saltzman E, Wilson PW, Jacques PF. Carbohydrate nutrition, insulin resistance, and the prevalence of the metabolic syndrome in the Framingham Offspring Cohort. Diabetes Care 27: 538 –546, 2004. 24. Morgan EE, Chandler MP, Young ME, McElfresh TA, Kung TA, Rennison JH, Tserng KY, Hoit BD, Stanley WC. Dissociation between gene and protein expression of metabolic enzymes in a rodent model of heart failure. Eur J Heart Fail 8: 687– 693, 2006. 25. Morrill AC, Chinn CD. The obesity epidemic in the United States. J Public Health Policy 25: 353–366, 2004. 26. Nakamura A, Rokosh DG, Paccanaro M, Yee RR, Simpson PC, Grossman W, Foster E. LV systolic performance improves with devel- 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 studies imply strain- and species-dependent effects of diet on cardiac remodeling and survival during pressure overload. The disparate effects of fructose diet compared with starch diet consumption on the response to pressure overload suggest that the two diets act through different mechanisms. In other words, the beneficial effects of the starch diet may be mediated by activation of cardioprotective pathways [as suggested by improved activity of mitochondrial enzymes (Fig. 4)] and by reduced stimulation of maladaptive cardiac responses activated by fructose diet feeding. High-sugar diets, in addition to being potentially damaging to renal function (35), may increase the production of proinflammatory cytokines (6, 7), which are important predictors of mortality in HF patients (2). While the present study establishes that a high-starch diet elicits a more favorable cardiac response to pressure overload than a high-sugar diet, additional discovery-based experimentation (e.g., gene chip and proteomic analyses) is needed to identify the mechanism(s) responsible for the dramatic differences between the two diets. In summary, the findings of the present study demonstrate that during chronic pressure overload, a high-starch diet prevents cardiac growth and remodeling while a diet high in simple sugar increases mortality and molecular markers of HF. Although current dietary recommendations suggest a highcarbohydrate/low-fat diet (21) and suggest minimizing the intake of sugar, there is nominal experimental evidence indicating that the risk for LVH and HF is affected by sugar consumption, particularly in the setting of hypertension. Our findings suggest that increasing sugar consumption has profound effects on the remodeling and contractile performance of the heart in response to pressure overload. The mechanism for these effects, however, remains unknown. Future studies should involve the use of transgenic mice, such as the cardiac insulin receptor knockout mouse, to target whether alterations in insulin signaling impact the development of LVH and the progression to HF. H1859 H1860 27. 28. 29. 30. 32. 33. 34. 35. opment of hypertrophy after transverse aortic constriction in mice. Am J Physiol Heart Circ Physiol 281: H1104 –H1112, 2001. O’Neill BT, Abel ED. Akt1 in the cardiovascular system: friend or foe? J Clin Invest 115: 2059 –2064, 2005. Okere IC, Chandler MP, McElfresh TA, Rennison JH, Sharov V, Sabbah HN, Tserng KY, Hoit BD, Ernsberger P, Young ME, Stanley WC. Differential effects of saturated and unsaturated fatty acid diets on cardiomyocyte apoptosis, adipose distribution, and serum leptin. Am J Physiol Heart Circ Physiol 291: H38 –H44, 2006. Okere IC, Chess DJ, McElfresh TA, Johnson J, Rennison J, Ernsberger P, Hoit BD, Chandler MP, Stanley WC. High-fat diet prevents cardiac hypertrophy and improves contractile function in the hypertensive dahl salt-sensitive rat. Clin Exp Pharmacol Physiol 32: 825– 831, 2005. Okere IC, Young ME, McElfresh TA, Chess DJ, Sharov VG, Sabbah HN, Hoit BD, Ernsberger P, Chandler MP, Stanley WC. Low carbohydrate/high-fat diet attenuates cardiac hypertrophy, remodeling, and altered gene expression in hypertension. Hypertension 48: 1116 –1123, 2006. Panchal AR, Stanley WC, Kerner J, Sabbah HN. Beta-receptor blockade decreases carnitine palmitoyl transferase I activity in dogs with heart failure. J Card Fail 4: 121–126, 1998. Pellieux C, Aasum E, Larsen TS, Montessuit C, Papageorgiou I, Pedrazzini T, Lerch R. Overexpression of angiotensinogen in the myocardium induces downregulation of the fatty acid oxidation pathway. J Mol Cell Cardiol 41: 459 – 466, 2006. Rosamond W, Flegal K, Friday G, Furie K, Go A, Greenlund K, Haase N, Ho M, Howard V, Kissela B, Kittner S, Lloyd-Jones D, McDermott M, Meigs J, Moy C, Nichol G, O’Donnell CJ, Roger V, Rumsfeld J, Sorlie P, Steinberger J, Thom T, Wasserthiel-Smoller S, Hong Y. Heart disease and stroke statistics–2007 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation 115: e69 – e171, 2007. Rutter MK, Parise H, Benjamin EJ, Levy D, Larson MG, Meigs JB, Nesto RW, Wilson PW, Vasan RS. Impact of glucose intolerance and insulin resistance on cardiac structure and function: sex-related differences in the Framingham Heart Study. Circulation 107: 448 – 454, 2003. Sanchez-Lozada LG, Tapia E, Jimenez A, Bautista P, Cristobal M, Nepomuceno T, Soto V, Avila-Casado C, Nakagawa T, Johnson RJ, AJP-Heart Circ Physiol • VOL 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. Herrera-Acosta J, Franco M. Fructose-induced metabolic syndrome is associated with glomerular hypertension and renal microvascular damage in rats. Am J Physiol Renal Physiol 292: F423–F429, 2007. Scaglioni S, Stival G, Giovannini M. Dietary glycemic load, overall glycemic index, and serum insulin concentrations in healthy schoolchildren. Am J Clin Nutr 79: 339 –340, 2004. Sharma N, Okere IC, Duda MK, Chess DJ, O’Shea KM, Stanley WC. Potential impact of carbohydrate and fat intake on pathological left ventricular hypertrophy. Cardiovasc Res 73: 257–268, 2007. Sharma N, Okere IC, Duda MK, Johnson J, Yuan CL, Chandler MP, Ernsberger P, Hoit BD, Stanley WC. High fructose diet increases mortality in hypertensive rats compared to a complex carbohydrate or high fat diet. Am J Hypertens 20: 403– 409, 2007. Shigematsu Y, Hara Y, Ohtsuka T, Ohgimoto A, Inoue K, Higaki J. Relation of genetic predisposition and insulin resistance to left ventricular hypertrophy in hypertension. Am J Hypertens 18: 457– 463, 2005. Shiojima I, Yefremashvili M, Luo Z, Kureishi Y, Takahashi A, Tao J, Rosenzweig A, Kahn CR, Abel ED, Walsh K. Akt signaling mediates postnatal heart growth in response to insulin and nutritional status. J Biol Chem 277: 37670 –37677, 2002. Skurk C, Izumiya Y, Maatz H, Razeghi P, Shiojima I, Sandri M, Sato K, Zeng L, Schiekofer S, Pimentel D, Lecker S, Taegtmeyer H, Goldberg AL, Walsh K. The FOXO3a transcription factor regulates cardiac myocyte size downstream of AKT signaling. J Biol Chem 280: 20814 –20823, 2005. Stanley WC, Recchia FA, Lopaschuk GD. Myocardial substrate metabolism in the normal and failing heart. Physiol Rev 85: 1093–1129, 2005. Stiefel P, Miranda ML, Rodriguez-Puras MJ, Garcia-Morillo S, Carneado J, Pamies E, Villar J. Glucose effectiveness is strongly related to left ventricular mass in subjects with stage I hypertension or highnormal blood pressure. Am J Hypertens 17: 146 –153, 2004. Tang WH, Francis GS. Novel pharmacological treatments for heart failure. Expert Opin Investig Drugs 12: 1791–1801, 2003. Tian R, Musi N, D’Agostino J, Hirshman MF, Goodyear LJ. Increased adenosine monophosphate-activated protein kinase activity in rat hearts with pressure-overload hypertrophy. Circulation 104: 1664 –1669, 2001. 293 • SEPTEMBER 2007 • www.ajpheart.org Downloaded from http://ajpheart.physiology.org/ by 10.220.33.4 on June 17, 2017 31. CARBOHYDRATE INTAKE AND CARDIAC HYPERTROPHY