Effects of diet-induced hypercholesterolemia and gold nanoparticles treatment on peripheral tissues

RODRIGUES, MATHEUS S.; MARTINS, JULIA N.; PAULA, GABRIELA C. DE; VENTURINI, LIGIA M.; SILVEIRA, GUSTAVO DE B.; STRECK, EMÍLIO L.; BUDNI, JOSIANI; ÁVILA, RICARDO A. MACHADO DE; BEM, ANDREZA F. DE; SILVEIRA, PAULO C.L.; OLIVEIRA, JADE DE

doi:10.1590/0001-3765202220211081

Abstract

Cholesterol is a lipid molecule of great biological importance to animal cells. Dysregulation of cholesterol metabolism leads to raised blood total cholesterol levels, a clinical condition called hypercholesterolemia. Evidence has shown that hypercholesterolemia is associated with the development of liver and heart disease. One of the mechanisms underlying heart and liver alterations induced by hypercholesterolemia is oxidative stress. In this regard, in several experimental studies, gold nanoparticles (AuNP) displayed antioxidant properties. We hypothesized that hypercholesterolemia causes redox system imbalance in the liver and cardiac tissues, and AuNP treatment could ameliorate it. Young adult male Swiss mice fed a regular rodent diet or a high cholesterol diet for eight weeks and concomitantly treated with AuNP (2.5 μg/kg) or vehicle by oral gavage. Hypercholesterolemia increased the nitrite concentration and glutathione (GSH) levels and decreased the liver’s superoxide dismutase (SOD) activity. Also, hypercholesterolemia significantly enhanced the reactive oxygen species (ROS) and GSH levels in cardiac tissue. Notably, AuNP promoted the redox system homeostasis, increasing the SOD activity in hepatic tissue and reducing ROS levels in cardiac tissue. Overall, our data showed that hypercholesterolemia triggered oxidative stress in mice’s liver and heart, which was partially prevented by AuNP treatment.

Key words
Antioxidant molecules; gold nanoparticles; hypercholesterolemia; oxidative stress; peripheral tissues

INTRODUCTION

Cholesterol, a compound of the steroid family, is a lipid molecule with great biological importance for all animal cells. Because of that, cells need a continuous supply of cholesterol. Most of it is derived from endogenous synthesis, and only a small amount of the body cholesterol is provided from the diet (IQWiG 2006IQWIG - INSTITUTE FOR QUALITY AND EFFICIENCY IN HEALTH CARE. 2006. What is cholesterol and how does arteriosclerosis develop?). Its metabolism occurs mainly in the liver, where cholesterol homeostasis maintenance is carried out by many mechanisms, such as biosynthesis, storage, and conversion into bile acids (Luo et al. 2020LUO J, YANG H & SONG BL. 2020. Mechanisms and regulation of cholesterol homeostasis. Nat Rev Mol Cell Biol 21: 225-245.). In this regard, dysregulation of body cholesterol homeostasis can lead to raised blood cholesterol levels, a clinical condition called hypercholesterolemia (Ibrahim et al. 2021IBRAHIM MA, ASUKA E & JIALAL I. 2021. Hypercholesterolemia. In: StatPearls. Treasure Island: StatPearls.).

Regardless of their etiology, high levels of plasma cholesterol contribute to the development of diseases (Nelson 2013NELSON RH. 2013. Hyperlipidemia as a risk factor for cardiovascular disease. Prim Care 40: 195-211., Csonka et al. 2017CSONKA C ET AL. 2017. Isolated hypercholesterolemia leads to steatosis in the liver without affecting the pancreas. Lipids Health Dis 16: 144.). Hypercholesterolemia is a well-known risk factor for developing cardiovascular disease (CVD), mainly related to atherosclerosis (Gidding & Allen 2019GIDDING SS & ALLEN NB. 2019. Cholesterol and Atherosclerotic Cardiovascular Disease: A Lifelong Problem. J Am Heart Assoc 8: e012924.). High blood cholesterol levels have also been shown to exert direct heart negative effects in a process that occurs independently of atherosclerosis disease (Csonka et al. 2016CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726.). Experimental evidence has reported that dietary cholesterol and hypercholesterolemia appear to be significant risk factors for liver steatosis (Wouters et al. 2008WOUTERS K ET AL. 2008. Dietary cholesterol, rather than liver steatosis, leads to hepatic inflammation in hyperlipidemic mouse models of nonalcoholic steatohepatitis. Hepatology 48: 474-486.). Importantly, epidemiological and clinical studies have shown a strong correlation between liver disease and the increase in several markers of subclinical atherosclerosis and carotid artery inflammation (Moon et al. 2015MOON SH, NOH TS & CHO YS. 2015. Association between nonalcoholic fatty liver disease and carotid artery inflammation evaluated by 18F-fluorodeoxyglucose positron emission tomography. Angiology 66: 472-480., Oni et al. 2013ONI ET ET AL. 2013. A systematic review: burden and severity of subclinical cardiovascular disease among those with nonalcoholic fatty liver; should we care?. Atherosclerosis 230: 258-267.). Dyslipidemia, arterial hypertension, liver inflammation, and increased reactive oxygen species (ROS) production seem to be the connective factors between liver and heart diseases (Byrne & Targher 2015BYRNE CD & TARGHER G. 2015 NAFLD: a multisystem disease. J Hepato 62: S47-S64.).

Oxidative stress is a condition characterized by a redox system imbalance that favors the ROS accumulation and oxidative damage to macromolecules (Burton & Jauniaux 2011BURTON GJ & JAUNIAUX E. 2011. Oxidative stress. Best Pract Res Clin Obstet Gynaecol 25: 287-299.), which is related to the initiation and progression of liver and heart diseases (Csonka et al. 2016CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726., Polimeni et al. 2015POLIMENI L, DEL BEN M, BARATTA F, PERRI L, ALBANESE F, PASTORI D, VIOLI F & ANGELICO F. 2015. Oxidative stress: New insights on the association of non-alcoholic fatty liver disease and atherosclerosis. World J Hepatol 7: 1325-1336.). Since hypercholesterolemia contributes to oxidative stress, managing oxidative stress can be a promising therapeutic strategy to prevent the liver and heart diseases linked to hypercholesterolemia. In this regard, experimental studies have shown critical antioxidant properties of gold nanoparticles (AuNP) administration in many diseases (Tsai et al. 2007TSAI CY, SHIAU AL, CHEN SY, CHEN YH, CHENG PC, CHANG MY, CHEN DH, CHOU CH, WANG CR & WU CL. 2007. Amelioration of collagen-induced arthritis in rats by nanogold. Arthritis Rheum 56: 544-554., Sumbayev et al. 2013SUMBAYEV VV, YASINSKA IM, GARCIA CP, GILLILAND D, LALL GS, GIBBS BF, BONSALL DR, VARANI L, ROSSI F & CALZOLAI L. 2013. Gold nanoparticles downregulate interleukin-1β-induced pro-inflammatory responses. Small 9: 472-477., Muller et al. 2017MULLER AP, FERREIRA GK, PIRES AJ, SILVEIRA GB, DE SOUZA DL, BRANDOLFI JA, DE SOUZA CT, PAULA MS & SILVEIRA PCL. 2017. Gold nanoparticles prevent cognitive deficits, oxidative stress and inflammation in a rat model of sporadic dementia of Alzheimer’s type. Mater Sci Eng C Mater Biol Appl 77: 476-483.), including therapeutic effects on the liver (Kabir et al. 2014KABIR N, ALI H, ATEEQ M, BERTINO M, SHAH M & FRANZEL L. 2014. Silymarin coated gold nanoparticles ameliorates CCl4-induced hepatic injury and cirrhosis through down regulation of hepatic stellate cells and attenuation of Kupffer cells. RSC Adv 4: 9012-9020.) and heart diseases (Qiao et al. 2017QIAO Y, ZHU B, TIAN A & LI Z. 2017. PEG-coated gold nanoparticles attenuate β-adrenergic receptor-mediated cardiac hypertrophy. Int J Nanomedicin 12: 4709-4719.). Scavenger action against ROS (Barathmanikanth et al. 2010BARATHMANIKANTH S, KALISHWARALAL K, SRIRAM M, PANDIAN S, YOUN HS, EOM S & GURUNATHAN S. 2010. Anti-oxidant effect of gold nanoparticles restrains hyperglycemic conditions in diabetic mice. J Nanobiotechnology 8: 16., Razzaq et al. 2016RAZZAQ H, SAIRA F, YAQUB A, QURESHI R, MUMTAZ M & SALEEMI S. 2016. Interaction of gold nanoparticles with free radicals and their role in enhancing the scavenging activity of ascorbic acid. J Photochem Photobiol B 161: 266-272.) and improvement of antioxidant defenses (Ko et al. 2020KO WC, SHIEH JM & WU WB. 2020. P38 MAPK and Nrf2 Activation Mediated Naked Gold Nanoparticle Induced Heme Oxygenase-1 Expression in Rat Aortic Vascular Smooth Muscle Cells. Arch Med Res 51: 388-396.) are among the mechanisms involved with the therapeutic effect of AuNP. Therefore, considering the peripheral consequences of hypercholesterolemia and the therapeutic effects of treatment with AuNP on the liver and cardiac tissues, this study aimed to investigate the effects of AuNP on the imbalance of the peripheral redox system associated with hypercholesterolemia.

MATERIALS AND METHODS

Animals

Male Swiss mice (three months old) weighing between 25 and 30g from the Central Animal House of Universidade do Extremo Sul Catarinense (UNESC, Brazil) were used. The animals were maintained in 9 to 10 animals per cage in plastic cages, with controlled temperature and light conditions. All animal procedures were performed following the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health (Bethesda, MD, USA) and with the Ethics Committee of the University of the UNESC under protocol 007/2018-1.

Gold nanoparticles synthesis

Gold nanoparticles (AuNP) of 20 nm were synthesized as described previously by Rodrigues et al. 2021RODRIGUES MS ET AL. 2021. Nanotechnology as a therapeutic strategy to prevent neuropsychomotor alterations associated with hypercholesterolemia. Colloids Surf B 201: 111608., which involved the chemical reduction of the metallic precursor tetrachloroauric acid (HAuCl₄; Sigma-Aldrich, MO) using the reducing agent and stabilizing sodium citrate (Na₃C₆H₅O₇.2H₂O; Nuclear, São Paulo, Brazil). The physical-chemical properties of AuNP used in our study were previously described in the literature. The average size of AuNP was confirmed by UV-vis, in which the nanoparticles exhibited a purple color and an absorption maximum of 524 nm. This size was confirmed by transmission electron microscopy (TEM) analysis, which demonstrated that nanoparticles present an oblong morphology (nearly spherical), and an average size of 20 nm (Della Vechia et al. 2020DELLA VECHIA IC ET AL. 2020. Comparative cytotoxic effect of citrate-capped gold nanoparticles with different sizes on noncancerous and cancerous cell lines. J Nanopart Res 22: 133.). Regarding its Zeta potential and hydrodynamic size, Della Vechia et al. (2020)DELLA VECHIA IC ET AL. 2020. Comparative cytotoxic effect of citrate-capped gold nanoparticles with different sizes on noncancerous and cancerous cell lines. J Nanopart Res 22: 133. showed that AuNP exhibits a Zeta potential of -42 ± 4 mv and hydrodynamic size of 26 ± 4nm. It is important to mention that the viability of AuNP at 70 mg/L was monitored every two days by UV-visible spectrometry. Before each administration, the AuNP solution at 70 mg/L was diluted in water to reach the working concentration of 0.25 µg/mL, resulting in a dose equivalence of 2.5 µg/kg body weight mice.

Experimental design

Young adult (three-month-old) male Swiss mice fed a normal rodent diet (22.53 % of protein, 41.02 % of carbohydrate, 8.75 % of fat, and calorie value of 3.3 kcal/g) or a high cholesterol diet (14.79 % of protein, 50.19 % of carbohydrate, 23.64 % of fat, 1.25% of cholesterol and calorie value of 4.7 kcal/g) continuously for eight weeks (Moreira et al. 2014MOREIRA EL, DE OLIVEIRA J, ENGEL DF, WALZ R, DE BEM AF, FARINA M & PREDIGER RDS. 2014. Hypercholesterolemia induces short-term spatial memory impairments in mice: up-regulation of acetylcholinesterase activity as an early and causal event?. J Neural Transm (Vienna) 121: 415-426., Rodrigues et al. 2021RODRIGUES MS ET AL. 2021. Nanotechnology as a therapeutic strategy to prevent neuropsychomotor alterations associated with hypercholesterolemia. Colloids Surf B 201: 111608.). Also, mice were, since the beginning of the experimental period, concomitantly treated with AuNP (2.5 μg/kg, in an aqueous solution) or with a vehicle solution (water) by oral gavage on alternate days for eight weeks, totalizing four experimental groups (n = 6 animals per experimental group). The animal’s body mass was measured every two days during all experimental period (eight weeks). Twenty-four hours after the last treatment section, the animals were food-deprived for 6 hours, and the blood was collected by cardiac puncture to determine plasma total cholesterol levels. After that, the mice’s cardiac and liver tissue were dissected to determine oxidative stress parameters (Figure 1a). It is important to mention that the dosage of 2.5 μg/kg used in our study does not have toxic effects on mice, evidenced by no changes in the levels of ALT in plasma and the levels of MTT in the liver, an essential marker of cell death. Other parameters were not modified, like the levels of γ-GT and creatinine on plasma, which reinforces the safe use of AuNP in the dose of 2.5 μg/kg in our study (Rodrigues et al. 2021RODRIGUES MS ET AL. 2021. Nanotechnology as a therapeutic strategy to prevent neuropsychomotor alterations associated with hypercholesterolemia. Colloids Surf B 201: 111608.).

Figure 1
Experimental protocol and the effects of high cholesterol diet and AuNP treatment on plasma cholesterol levels. (a) Experimental protocol. The animals were exposed for eight weeks to a normal diet (3.3 kcal/g) or a high cholesterol diet (1.25% cholesterol and 20% saturated fat; calorie value of 4.7 kcal/g). Concomitantly, the animals were treated with AuNP (2.5 μg/kg, in aqueous solution) or vehicle solution (water) by oral gavage every two days. Twenty-four hours after the last treatment section, the animals were food-deprived for 6 hours, and the blood was collected by cardiac puncture to determine plasma total cholesterol levels. After that, the mice’s cardiac and liver tissue were dissected for further determination of oxidative stress parameters. (b) Plasma cholesterol levels. (c) Evaluation of body mass throughout the experimental period. Data are shown as mean ± SD (n = 6 animals per group). * p <0.05 versus normal diet and vehicle group (Two-way ANOVA followed by Duncan post hoc test).

Plasma total cholesterol levels

The animals’ blood was collected from the animals’ hearts under previous anesthesia with ketamine and xylazine (75 and 10 mg/kg, respectively, i.p.). The blood was immediately centrifuged, and the plasma was collected. According to the manufacturer’s instructions, total cholesterol levels were measured in plasma using a commercial kit (Gold Analisa Diagnostica Ltda, Minas Gerais, Brazil). The data are expressed as mg/dL.

Determination of intracellular reactive oxygen species (ROS)

The intracellular levels of oxidized 2,7-dichlorodihydrofluorescein (DCF) were measured based on the oxidation of the 2’,7’-dichlorodihydrofluorescein diacetate (DCFH-DA) probe to a 2’,7’-dichlorodihydrofluorescein (DCF) fluorescent compound, as previously described (Hempel et al. 1999HEMPEL SL, BUETTNER GR, O’MALLEY YQ, WESSELS DA & FLAHERTY DM. 1999. Dihydrofluorescein diacetate is superior for detecting intracellular oxidants: comparison with 2’,7’-dichlorodihydrofluorescein diacetate, 5(and 6)-carboxy-2’,7’-dichlorodihydrofluorescein diacetate, and dihydrorhodamine 123. Free Radic Biol Med 27: 146-159.). The sample was incubated with 10 mM DCFH-DA at 37 °C for 30 minutes. DCF-DA is de-esterified inside cells by endogenous esterases to the ionized free acid, DCFH. DCFH is oxidized to 2,7-dichlorofluorescein (DCF) by reactive species. The formation of this oxidized fluorescent derivative was monitored with the excitation and emission wavelengths of 488 and 525 nm, respectively, using a fluorescence spectrophotometer. A DCF standard curve was constructed using DCF (concentration of 10 nM) as an internal control in the experiment. Data are expressed as U of fluorescence/mg of protein.

Determination of intracellular nitric oxide

Nitric oxide was estimated spectrophotometrically from the stable metabolite nitrite production, derived from the action of nitric oxide (NO) on O₂ ^-. At room temperature, the samples were incubated with Griess reagent (1% sulfanilamide in 0.1 mol/L and 0.1% N-[1-naphthyl] ethylene diamine dihydrochloride) for 10 minutes, and the absorbance was measured at 540 nm using a microplate reader. The nitrite content was calculated based on a standard curve from 0 to 100nm performed with the sodium nitrite metabolite (NaNO₂). The results are expressed as µmol Nitrite/mg of protein (Chae et al. 2004CHAE SY, LEE M, KIM SW & BAE YH. 2004. Protection of insulin secreting cells from nitric oxide induced cellular damage by crosslinked hemoglobin. Biomaterials 25: 843-850.).

Protein carbonylation content

Measurement of protein carbonyl content has been used as a marker of oxidative damage to proteins. Protein oxidation was measured using labeled protein-hydrazone derivatives with 2,4-dinitrophenylhydrazine. These derivatives were extracted with trichloroacetic acid, followed by ethanol/ethyl acetate treatment, and dissolved in urea hydrochloride. This reaction generates the formation of incorporated 2,4-dinitrophenylhydrazine, which was determined spectrophotometrically at 370 nm, as previously described by Levine et al. (1990)LEVINE RL, GARLAND D, OLIVER CN, AMICI A, CLIMENT I, LENZ AG, AHN BW, SHALTIEL S & STADTMAN ER. 1990. Determination of carbonyl content in oxidatively modified proteins. Methods Enzymol 186: 464-478.. Values are expressed as nmol/mg of protein.

Superoxide dismutase (SOD) activity

The SOD activity was measured by inhibiting adrenaline’s oxidation adapted from Bannister & Calabrese (1987)BANNISTER JV & CALABRESE L. 1987. Assays for superoxide dismutase. Methods Biochem Anal 32: 279-312.. For this, the samples were previously homogenized in PBS buffer, and from this homogenate, three different sample volumes (5, 10, and 15 µL) were removed. 5 µL of catalase (0.0024 mg / mL of distilled water) was added to these volumes. Then, a glycine buffer in variable volume was added according to the number of samples. After these processes, a baseline reading was performed. Then, 5 µL of adrenaline (60 mM in distilled water + 15 mL/mL of steaming hydrochloric acid (HCl) was added, and the kinetics were visualized. The readings were taken for 180s at 10s intervals and measured in an ELISA reader at 480nm. Results are expressed as U of SOD/mg of protein.

Reduced glutathione (GSH) levels

The GSH content was measured in homogenate after protein precipitation with 0.6M perchloric acid and centrifugation at 4 °C for 10 minutes. The resulting supernatant was incubated with 800 mM phosphate buffer (pH 7.4) and 1 mg/mL of ortho-phthalaldehyde (OPT) for 15 minutes at room temperature. The resulting color development from OPT and thiols’ reaction reaches a maximum of 5 minutes and remains stable for more than 30 minutes. After 10 minutes, the fluorescence intensity was determined (emission wavelength of 420 nm and 350 nm of excitation). A standard, reduced glutathione curve was used to calculate the samples’ GSH levels (Hissin & Hilf 1976HISSIN PJ & HILF R. 1976. A fluorometric method for determination of oxidized and reduced glutathione in tissues. Anal Biochem 74: 214-226.). The results are expressed as U fluorescence/mg of protein.

Determination of protein content

The protein content was quantified using bovine serum albumin as a standard, as Lowry et al. (1951)LOWRY OH, ROSEBROUGH NJ, FARR AL & RANDALL RJ. 1951. Protein measurement with the Folin phenol reagent. J Biol Chem 193: 265-275. described previously. Absorbance was measured in a SpectraMax M5 microplate reader at a wavelength of 700nm.

Statistical analysis

All results were presented as mean ± SD. The statistical analysis was carried out using the two-way analysis of variance (ANOVA), followed by the Duncan test when appropriate. The results were considered significant when p ≤ 0.05. Statistical tests were performed using the Statistica® program.

RESULTS

Hypercholesterolemic diet caused an increase in total plasma cholesterol levels

As shown in Figure 1b, the animals’ exposure to a hypercholesterolemic diet for eight weeks caused a significant increase in the total plasma cholesterol levels. The AuNP treatment did not change the cholesterol levels in mice fed either a normal diet or high cholesterol diet. In addition, analyzing the animals’ body weight over the weeks, we noticed that hypercholesterolemic animals had higher body weight in the seventh week than other experimental groups. No effect of the AuNP administration was observed in the animal’s body weight, regardless of the diet (Figure 1c).

Effects of hypercholesterolemic diet and AuNP treatment on oxidative stress parameters in hepatic tissue

The effects of high cholesterol diet and AuNP treatment on oxidative stress parameters in hepatic tissue are shown in Figure 2. Levels of ROS and nitrite were used as oxidative parameters. High cholesterol diet significantly increased the ROS and nitrite levels in the liver, which was not prevented by AuNP treatment (Figure 2a, 2b).

Figure 2
Effects of hypercholesterolemia and AuNP treatment on oxidative stress parameters in hepatic tissue. (a) ROS levels, (b) Nitrite concentrations, (c) SOD activity, (d) GSH content, and (e) carbonyl levels. Data are shown as mean ± SD (n = 6 animals per group). * p <0.05 versus normal diet and vehicle group; # p <0.05 versus normal diet and AuNP group; & p <0.05 versus high cholesterol diet and vehicle group (Two-way ANOVA followed by Duncan post hoc test).

The GSH levels and SOD activity were measured to evaluate the antioxidant system. Hypercholesterolemic diet significantly reduced the SOD activity in the hepatic tissue of mice. Notably, AuNP treatment ameliorated the SOD activity in mice’s liver exposed to a high cholesterol diet (Figure 2c). We observed that a high cholesterol diet induced a significant increase in the hepatic GSH levels of animals, which was not changed by AuNP treatment (Figure 2d). Furthermore, carbonyl levels were used as a measure of oxidative protein damage. No diet and AuNP treatment effects were observed regarding the carbonyl levels in hepatic tissue (Figure 2e).

Impact of hypercholesterolemic diet and AuNP treatment on oxidative stress parameters in cardiac tissue

The effects of hypercholesterolemia and AuNP administration in the heart were also investigated. The hypercholesterolemic diet significantly increased the ROS levels in the cardiac tissue, which were reduced by the AuNP treatment (Figure 3a). No effect of the high cholesterol diet and AuNP treatment was observed in nitrite levels in this same tissue (Figure 3b).

Figure 3
Effects of hypercholesterolemia and AuNP treatment on oxidative stress parameters in cardiac tissue. (a) ROS levels, (b) Nitrite concentrations, (c) SOD activity, (d) GSH content, and (e) carbonyl levels. Data are shown as mean ± SD (n = 6 animals per group). * p <0.05 versus normal diet and vehicle group; & p <0.05 versus high cholesterol diet and vehicle group (Two-way ANOVA followed by Duncan post hoc test).

Evaluation of the antioxidant system showed that the hypercholesterolemic diet induced an enhancement in the levels of GSH in the cardiac tissue, while the AuNP treatment reduced these antioxidant levels in hypercholesterolemic mice (Figure 3d). Moreover, no effect of diet and AuNP treatment was observed regarding the SOD activity in the heart (Figure 3c). Finally, as shown in figure 3e, the hypercholesterolemic diet tended to increase carbonyl levels in cardiac tissue (p= 0.149), which was not modified by AuNP treatment.

DISCUSSION

Alterations in cholesterol metabolism can lead to the development of pathologies (Ibrahim et al. 2021IBRAHIM MA, ASUKA E & JIALAL I. 2021. Hypercholesterolemia. In: StatPearls. Treasure Island: StatPearls.). Hypercholesterolemia exerts direct negative effects on the heart, being a well-known cardiovascular risk factor (Gidding & Allen 2019GIDDING SS & ALLEN NB. 2019. Cholesterol and Atherosclerotic Cardiovascular Disease: A Lifelong Problem. J Am Heart Assoc 8: e012924., Csonka et al. 2016CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726.). High serum cholesterol levels can also impair liver function and contribute to liver steatosis occurrence (Wouters et al. 2008WOUTERS K ET AL. 2008. Dietary cholesterol, rather than liver steatosis, leads to hepatic inflammation in hyperlipidemic mouse models of nonalcoholic steatohepatitis. Hepatology 48: 474-486.). Oxidative stress appears to be the connective factor between hypercholesterolemia and heart and liver diseases (Csonka et al. 2016CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726., Polimeni et al. 2015POLIMENI L, DEL BEN M, BARATTA F, PERRI L, ALBANESE F, PASTORI D, VIOLI F & ANGELICO F. 2015. Oxidative stress: New insights on the association of non-alcoholic fatty liver disease and atherosclerosis. World J Hepatol 7: 1325-1336.). Since oxidative stress contributes to endothelial dysfunction (Elahi & Matata 2015ELAHI M & MATATA B. 2015. Blood-dependent redox activity during extracorporeal circulation in health and disease. The Cardiology 1: 156-157.), cardiac injury (Wilson et al. 2002WILSON SH, BEST PJ, EDWARDS WD, HOLMES JR DR, CARLSON PJ, CELERMAJER DS & LERMAN A. 2002. Nuclear factor-kappaB immunoreactivity is present in human coronary plaque and enhanced in patients with unstable angina pectoris. Atherosclerosis 160: 147-153.), atherosclerosis (Mangge et al. 2014MANGGE H, BECKER K, FUCHS D & GOSTNER JM. 2014. Antioxidants, inflammation and cardiovascular disease. World J Cardiol 6: 462-477.), and liver steatosis progression (Wouters et al. 2008WOUTERS K ET AL. 2008. Dietary cholesterol, rather than liver steatosis, leads to hepatic inflammation in hyperlipidemic mouse models of nonalcoholic steatohepatitis. Hepatology 48: 474-486.), the management of oxidative stress in these organs is of great relevance. In this context, the AuNP, due to its significant antioxidant properties (Tsai et al. 2007TSAI CY, SHIAU AL, CHEN SY, CHEN YH, CHENG PC, CHANG MY, CHEN DH, CHOU CH, WANG CR & WU CL. 2007. Amelioration of collagen-induced arthritis in rats by nanogold. Arthritis Rheum 56: 544-554., Sumbayev et al. 2013SUMBAYEV VV, YASINSKA IM, GARCIA CP, GILLILAND D, LALL GS, GIBBS BF, BONSALL DR, VARANI L, ROSSI F & CALZOLAI L. 2013. Gold nanoparticles downregulate interleukin-1β-induced pro-inflammatory responses. Small 9: 472-477., Muller et al. 2017MULLER AP, FERREIRA GK, PIRES AJ, SILVEIRA GB, DE SOUZA DL, BRANDOLFI JA, DE SOUZA CT, PAULA MS & SILVEIRA PCL. 2017. Gold nanoparticles prevent cognitive deficits, oxidative stress and inflammation in a rat model of sporadic dementia of Alzheimer’s type. Mater Sci Eng C Mater Biol Appl 77: 476-483.), might be an important therapeutic intervention to mitigate the peripheral consequences of hypercholesterolemia. In this regard, we aimed to investigate AuNP treatment’s effects on peripheral consequences of hypercholesterolemia, focusing mainly on changes in the redox system in cardiac and liver tissues.

We exposed Swiss mice to a high cholesterol diet (1.25% of cholesterol) for eight weeks to study hypercholesterolemia’s peripheral consequences to cardiac and hepatic tissues. As expected, the hypercholesterolemic diet intake significantly increased the animals’ total plasma cholesterol levels compared to the animals fed a regular diet, thus characterizing an experimental hypercholesterolemia model. Our findings follow previous studies, which used the same experimental protocol to induce hypercholesterolemia in mice (Moreira et al. 2014MOREIRA EL, DE OLIVEIRA J, ENGEL DF, WALZ R, DE BEM AF, FARINA M & PREDIGER RDS. 2014. Hypercholesterolemia induces short-term spatial memory impairments in mice: up-regulation of acetylcholinesterase activity as an early and causal event?. J Neural Transm (Vienna) 121: 415-426., Rodrigues et al. 2021RODRIGUES MS ET AL. 2021. Nanotechnology as a therapeutic strategy to prevent neuropsychomotor alterations associated with hypercholesterolemia. Colloids Surf B 201: 111608.). Similarly, mice fed a high cholesterol diet containing 1.5% of cholesterol for eight weeks showed an increase of about 30% in plasma cholesterol levels (de Souza et al. 2019DE SOUZA RM, DE SOUZA L, MACHADO AE, ALVES AC, RODRIGUES FS, AGUIAR JR AS, DOS SANTOS ARS, DE BEM AF & MOREIRA ELG. 2019. Behavioural, metabolic and neurochemical effects of environmental enrichment in high-fat cholesterol-enriched diet-fed mice. Behav Brain Res 359: 648-656.). In fact, the experimental strategy of hypercholesterolemia induced by diet to mimic human hypercholesterolemia is well described in the literature (Thirumangalakudi et al. 2008THIRUMANGALAKUDI L, PRAKASAM A, ZHANG R, BIMONTE-NELSON H, SAMBAMURTI K, KINDY MS & BHAT NR. 2008. High cholesterol-induced neuroinflammation and amyloid precursor protein processing correlate with loss of working memory in mice. J Neurochem 106: 475-485., de Oliveira et al. 2011DE OLIVEIRA J, HORT MA, MOREIRA EL, GLASER V, RIBEIRO-DO-VALLE RM, PREDIGER RD, FARINA M, LATINI A & DE BEM AF. 2011. Positive correlation between elevated plasma cholesterol levels and cognitive impairments in LDL receptor knockout mice: relevance of cortico-cerebral mitochondrial dysfunction and oxidative stress. Neuroscience 197: 99-106., Moreira et al. 2014MOREIRA EL, DE OLIVEIRA J, ENGEL DF, WALZ R, DE BEM AF, FARINA M & PREDIGER RDS. 2014. Hypercholesterolemia induces short-term spatial memory impairments in mice: up-regulation of acetylcholinesterase activity as an early and causal event?. J Neural Transm (Vienna) 121: 415-426.).

The liver is the central organ of cholesterol and lipid metabolism in the body (Luo et al. 2020LUO J, YANG H & SONG BL. 2020. Mechanisms and regulation of cholesterol homeostasis. Nat Rev Mol Cell Biol 21: 225-245., Ponziani et al. 2015PONZIANI FR, PECERE S, GASBARRINI A & OJETTI V. 2015. Physiology and pathophysiology of liver lipid metabolism. Expert Rev Gastroenterol Hepatol 9: 1055-1067.). Importantly, high cholesterol intake from the diet is related to the induction of advanced liver disease stages (Ichimura et al. 2017ICHIMURA M ET AL. 2017. A diet-induced Sprague-Dawley rat model of nonalcoholic steatohepatitis-related cirrhosis. J Nutr Biochem 40: 62-69.). High cholesterol content and accumulation led to hepatic oxidative stress and inflammation, favoring liver disease (Püschel & Henkel 2019PÜSCHEL GP & HENKEL J. 2019. Dietary cholesterol does not break your heart but kills your liver. Porto Biomed J 3: e12.). Here, to better assess the impact of dietary cholesterol and consequent hypercholesterolemia on liver function, we evaluate oxidative stress parameters in the hepatic tissue of mice exposed to a high cholesterol diet. We observed a significant increase in nitrite levels in the liver of hypercholesterolemic mice. The stable and measurable metabolite nitrite was evaluated as an indicator of nitric oxide (NO) production. Also, NO reaction with superoxide anion (O₂ ^-) produces the peroxynitrite (ONOO^-) anion, a molecule with strong oxidizing properties. Previous studies have pointed out that this reaction is exacerbated by clinical conditions that lead to endothelial and mitochondrial disorders, such as hypercholesterolemia (Madamanchi & Runge 2007MADAMANCHI NR & RUNGE MS. 2007. Mitochondrial dysfunction in atherosclerosis. Circ Res 100: 460-473., Knight-Lozano et al. 2002KNIGHT-LOZANO CA, YOUNG CG, BUROW DL, HU ZY, UYEMINAMI D, PINKERTON KE, ISCHIROPOULOS H & BALLINGER SW. 2002. Cigarette smoke exposure and hypercholesterolemia increase mitochondrial damage in cardiovascular tissues. Circulation 105: 849-854.). Evidence showed that a cholesterol-rich diet induced an increase of NO synthase inducible (iNOS) mRNA expression in rat liver and of NO content in hepatic cells (Kim et al. 2002KIM JW, KANG KW, OH GT, SONG J, KIM ND & PAK YK. 2002. Induction of hepatic inducible nitric oxide synthase by cholesterol in vivo and in vitro. Exp Mol Med 34: 137-144.), which could trigger an important role in the pathology of liver diseases (Iwakiri & Kim 2015IWAKIRI Y & KIM MY. 2015. Nitric oxide in liver diseases. Trends Pharmacol Sci 36: 524-536.). The effect of high cholesterol levels in hepatic dysfunction became more evident by reducing liver fibrosis and nitric oxide synthase expression in response to simvastatin in rats, a drug with hypocholesterolemic action (Wang et al. 2013WANG W, ZHAO C, ZHOU J, ZHEN Z, WANG Y & SHEN C. 2013. Simvastatin ameliorates liver fibrosis via mediating nitric oxide synthase in rats with non-alcoholic steatohepatitis-related liver fibrosis. PLoS ONE 8: e76538.). To better assess the effect of hypercholesterolemia in reactive species production, we performed analyses of ROS levels. Our data showed a significant effect of hypercholesterolemia on hepatic ROS levels. Likewise, Enríquez-Cortina et al. (2017)ENRÍQUEZ-CORTINA C, BELLO-MONROY O & ROSALES-CRUZ P. 2017. Cholesterol overload in the liver aggravates oxidative stress-mediated DNA damage and accelerates hepatocarcinogenesis. Oncotarget 8: 104136-104148. showed higher ROS content, measured by the DCFH technique, in response to a high cholesterol diet in mice’s liver (Enríquez-Cortina et al. 2017ENRÍQUEZ-CORTINA C, BELLO-MONROY O & ROSALES-CRUZ P. 2017. Cholesterol overload in the liver aggravates oxidative stress-mediated DNA damage and accelerates hepatocarcinogenesis. Oncotarget 8: 104136-104148.). Since increased levels of nitrite and ROS lead to oxidative stress, our results showed that ingestion of a hypercholesterolemic diet causes increased oxidative stress in the liver tissue of mice.

One of the primary cellular defenses against the increase in ROS and nitrite is a group of oxidoreductases called SOD, critical antioxidant enzymes produced in the early stage of free radical generation (Chung 2017CHUNG WH. 2017. Unraveling new functions of superoxide dismutase using yeast model system: Beyond its conventional role in superoxide radical scavenging. J Microbiol 55: 409-416.). Here, we observed a SOD activity reduction in response to hypercholesterolemia in the hepatic tissue of mice. Corroborating with our findings, rats fed a high cholesterol diet exhibited worsened antioxidant defenses, evidenced by the low activity of the enzymes SOD and catalase in hepatocytes (Zou et al. 2005ZOU Y, LU Y & WEI D. 2005. Hypocholesterolemic effects of a flavonoid-rich extract of Hypericum perforatum L. in rats fed a cholesterol-rich diet. J Agric Food Chem 53: 2462-2466.). Three weeks of consumption of a cholesterol-rich diet was already able to reduce the activity of SOD in the rat’s liver (Amin & Abd El-Twab 2009AMIN KA & ABD EL-TWAB TM. 2009. Oxidative markers, nitric oxide and homocysteine alteration in hypercholesterolimic rats: role of atorvastatine and cinnamon. Int J Clin Exp Med 2: 254-265.). Also, hypercholesterolemic rabbits exhibited reduced SOD activity in the liver in response to high cholesterol diet exposure for four weeks (Ashry et al. 2020ASHRY NA, ABDЕLAZIZ RR & SUDDЕK GM. 2020. The potential effect of imatinib against hypercholesterolemia induced atherosclerosis, endothelial dysfunction and hepatic injury in rabbits. Life Sci 243: 117275.). Another important molecule of the antioxidant system is GSH. The reduced GSH is the co-substrate of glutathione peroxidase, which catalyzes, through the glutathione cycle, the reduction of hydrogen peroxide previously produced by SOD (Gaucher et al. 2018GAUCHER C, BOUDIER A, BONETTI J, CLAROT I, LEROY P & PARENT M. 2018. Glutathione: Antioxidant Properties Dedicated to Nanotechnologies. Antioxidants (Basel) 7: 62.). The antioxidant system is composed of enzymatic and non-enzymatic antioxidants (Birben et al. 2012BIRBEN E, SAHINER UM, SACKESEN C, ERZURUM S & KALAYCI O. 2012. Oxidative stress and antioxidant defense. World Allergy Organ J 5: 9-19.). In our study, the hypercholesterolemic animals exhibited an increase in GSH levels in hepatic tissue. This data is according to a previous work in which rats showed an increase in hepatic GSH levels in response to a hypercholesterolemic diet (Manjunatha & Srinivasan 2007MANJUNATHA H & SRINIVASAN K. 2007. Hypolipidemic and antioxidant effects of dietary curcumin and capsaicin in induced hypercholesterolemic rats. Lipids 42: 1133-1142.). In this same study, hypercholesterolemia has been associated with increased total thiol levels and decreased oxidative damage in the liver (Manjunatha & Srinivasan 2007MANJUNATHA H & SRINIVASAN K. 2007. Hypolipidemic and antioxidant effects of dietary curcumin and capsaicin in induced hypercholesterolemic rats. Lipids 42: 1133-1142.), suggesting that GSH plays a vital role in protecting liver tissue from oxidative damage induced by hypercholesterolemia. We found that the increase in hepatic GSH content was related to the absence of oxidative damage to the liver proteins, evidenced by no change in carbonyl group content in the liver of hypercholesterolemic animals. A similar compensatory effect was observed in the GSH content in brain structures of low-density lipoprotein receptor knockout (LDLr^-/^-) mice, an animal model to study familial hypercholesterolemia (de Oliveira et al. 2014DE OLIVEIRA J, MOREIRA EL, DOS SANTOS D, PIERMARTIRI T, DUTRA R, PINTON S, TASCA C, FARINA M, PREDIGER R & DE BEM AF. 2014. Increased susceptibility to amyloid-β-induced neurotoxicity in mice lacking the low-density lipoprotein receptor. J Alzheimers Dis 41: 43-60.). These facts reinforce the role of GSH in maintaining redox balance in response to hypercholesterolemia, including in the liver.

Previous evidence demonstrated that hypercholesterolemia increases oxidative stress and can affect the heart’s functioning (Csont et al. 2007CSONT T ET AL. 2007. Hypercholesterolemia increases myocardial oxidative and nitrosative stress thereby leading to cardiac dysfunction in apoB-100 transgenic mice. Cardiovasc Res 76: 100-109., Csonka et al. 2016CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726.). Herein, a significant effect of hypercholesterolemia was observed in the ROS levels, but not in nitrite formation, in mice’s cardiac tissue. Similarly, hypercholesterolemic animals presented increased ROS generation in many tissues, including the heart (Oliveira et al. 2005OLIVEIRA HC, COSSO RG, ALBERICI LC, MACIEL EM, SALERNO AG, DORIGHELLO GG, VELHO JA, DE FARIA EC & VERCESI AE. 2005. Oxidative stress in atherosclerosis-prone mouse is due to low antioxidant capacity of mitochondria. FASEB J 19: 278-280., Csont et al. 2007CSONT T ET AL. 2007. Hypercholesterolemia increases myocardial oxidative and nitrosative stress thereby leading to cardiac dysfunction in apoB-100 transgenic mice. Cardiovasc Res 76: 100-109.). Our data also agrees with Csont et al. (2007)CSONT T ET AL. 2007. Hypercholesterolemia increases myocardial oxidative and nitrosative stress thereby leading to cardiac dysfunction in apoB-100 transgenic mice. Cardiovasc Res 76: 100-109., which did not observe changes in the cardiac content of NO and nitric oxide synthase activity in mice fed a high cholesterol diet (Csont et al. 2007CSONT T ET AL. 2007. Hypercholesterolemia increases myocardial oxidative and nitrosative stress thereby leading to cardiac dysfunction in apoB-100 transgenic mice. Cardiovasc Res 76: 100-109.). During hypercholesterolemia, the balance between ROS and NO in the cardiovascular system is altered in a process that favors an increase in ROS and a decrease in NO biosynthesis (Stokes et al. 2002STOKES KY, COOPER D, TAILOR A & GRANGER DN. 2002. Hypercholesterolemia promotes inflammation and microvascular dysfunction: role of nitric oxide and superoxide. Free Radic Biol Med 33: 1026-1036.). Therefore, ROS-dependent mechanisms predominate compared to NO-dependent, which are inhibited. This phenomenon may partially explain the absence of an effect of hypercholesterolemia on nitrite levels in the heart and the presence of an effect of hypercholesterolemia on cardiac ROS levels observed in our study. In addition, like hepatic tissue, we observed that hypercholesterolemia increased GSH levels in cardiac tissue but did not alter SOD activity. Literature data showed that the effect of hypercholesterolemia on GSH levels in the heart directly depends on the time of exposure of the animals to the high cholesterol diet. Reduced levels of GSH were found in the heart of hypercholesterolemic animals exposed to a high cholesterol diet for 28 days (Deori et al. 2016DEORI M, DEVI D, KUMARI S, HAZARIKA A, KALITA H, SARMA R & DEVI R. 2016. Antioxidant Effect of Sericin in Brain and Peripheral Tissues of Oxidative Stress Induced Hypercholesterolemic Rats. Front Pharmacol 7: 319.) and six weeks (AlSaad et al. 2020ALSAAD AM, MOHANY M, ALMALKI MS, ALMUTHAM I, ALAHMARI A, ALSULAMAIN M & AL-REJAIE S. 2020. Baicalein Neutralizes Hypercholesterolemia-Induced Aggravation of Oxidative Injury in Rats. Int J Med Sci 17: 1156-1166.). Evaluating the effect of high cholesterol diet on GSH levels in cardiac tissue of LDLr^-/^- mice, Girod et al. 1999GIROD WG, JONES SP, SIEBER N, AW TY & LEFER DJ. 1999. Effects of hypercholesterolemia on myocardial ischemia-reperfusion injury in LDL receptor-deficient mice. Arterioscler Thromb Vasc Biol 19: 2776-2781. observed that animals exposed to the diet for twelve weeks showed a significant increase in GSH levels in this tissue (Girod et al. 1999GIROD WG, JONES SP, SIEBER N, AW TY & LEFER DJ. 1999. Effects of hypercholesterolemia on myocardial ischemia-reperfusion injury in LDL receptor-deficient mice. Arterioscler Thromb Vasc Biol 19: 2776-2781.). Interestingly, our study observed that a shorter exposure time of the animals to the diet could raise the GSH content in the heart of hypercholesterolemic mice. An increase of GSH levels was also observed in cardiac tissue of LDLr^-/^- treated with an antioxidant compound (Diphenyl diselenide), which reinforces the effect of hypercholesterolemia in the GSH levels in cardiac tissue of hypercholesterolemic mice (Mancini et al. 2013MANCINI G, DE OLIVEIRA J, HORT MA, MOREIRA ELG, RIBEIRO-DO-VALLE RM, ROCHA JBT & DE BEM AF. 2013. Diphenyl diselenide differently modulates cardiovascular redox responses in young adult and middle-aged low-density lipoprotein receptor knockout hypercholesterolemic mice. J Pharm Pharmacol 66: 387-397.).

Despite the increased GSH content in the heart of hypercholesterolemic mice, this improvement in antioxidant defense did not translate into a decrease in oxidative damage, as evidenced by a trend of increasing carbonyl levels in cardiac tissue of mice fed a high cholesterol diet. This finding agrees with previous studies, in which animals with diet-induced hypercholesterolemia exhibit high carbonyl levels in heart tissue (Sozen et al. 2018SOZEN E, YAZGAN B, SAHIN A, INCE U & OZER NK. 2018. High Cholesterol Diet-Induced Changes in Oxysterol and Scavenger Receptor Levels in Heart Tissue. Oxid Med Cell Longev 2018: 8520746., Sozer 2015SOZER V. 2015. Ameliorative effect of statin therapy on oxidative damage in heart tissue of hypercholesterolemic rabbits. Fundam Clin Pharmacol 29: 558-566.). Hypercholesterolemia was also related to increased oxidative damage to lipids (AlSaad et al. 2020ALSAAD AM, MOHANY M, ALMALKI MS, ALMUTHAM I, ALAHMARI A, ALSULAMAIN M & AL-REJAIE S. 2020. Baicalein Neutralizes Hypercholesterolemia-Induced Aggravation of Oxidative Injury in Rats. Int J Med Sci 17: 1156-1166., Sozer 2015SOZER V. 2015. Ameliorative effect of statin therapy on oxidative damage in heart tissue of hypercholesterolemic rabbits. Fundam Clin Pharmacol 29: 558-566.) and DNA (Chtourou et al. 2015CHTOUROU Y, SLIMA AB, MAKNI M, GDOURA R & FETOUI H. 2015. Naringenin protects cardiac hypercholesterolemia-induced oxidative stress and subsequent necroptosis in rats. Pharmacol Rep 67: 1090-1097.) in cardiac tissue. Of particular interest, some of these negative effects of hypercholesterolemia on oxidative stress have been prevented by treatment with substances with antioxidant properties (AlSaad et al. 2020ALSAAD AM, MOHANY M, ALMALKI MS, ALMUTHAM I, ALAHMARI A, ALSULAMAIN M & AL-REJAIE S. 2020. Baicalein Neutralizes Hypercholesterolemia-Induced Aggravation of Oxidative Injury in Rats. Int J Med Sci 17: 1156-1166., Sozer 2015SOZER V. 2015. Ameliorative effect of statin therapy on oxidative damage in heart tissue of hypercholesterolemic rabbits. Fundam Clin Pharmacol 29: 558-566., Chtourou et al. 2015CHTOUROU Y, SLIMA AB, MAKNI M, GDOURA R & FETOUI H. 2015. Naringenin protects cardiac hypercholesterolemia-induced oxidative stress and subsequent necroptosis in rats. Pharmacol Rep 67: 1090-1097.).

An antioxidant substance reduces or prevents macromolecules’ oxidation by ROS, acting as an inhibitor of ROS production or as a positive regulator of antioxidant defense (Mut-Salud et al. 2016MUT-SALUD N, ÁLVAREZ PJ, GARRIDO JM, CARRASCO E, ARÁNEGA A & RODRÍGUEZ-SERRANO F. 2016. Antioxidant Intake and Antitumor Therapy: Toward Nutritional Recommendations for Optimal Results. Oxid Med Cell Longev 2016: 6719534.). In this context, nanoparticles’ study as an antioxidant compound has grown due to their biocompatibility, high stability, and target delivery (Kumar et al. 2020KUMAR H, BHARDWAJ K, NEPOVIMOVA E, KUČA K, DHANJAL DS, BHARDWAJ S, BHATIA SK, VERMA R & KUMAR D. 2020. Antioxidant Functionalized Nanoparticles: A Combat against Oxidative Stress. Nanomaterials (Basel) 10: 1334.). Among these nanoparticles with antioxidant action are AuNP. The experimental use of AuNP has demonstrated important antioxidant and therapeutic properties in many diseases, including metabolic diseases (Barathmanikanth et al. 2010BARATHMANIKANTH S, KALISHWARALAL K, SRIRAM M, PANDIAN S, YOUN HS, EOM S & GURUNATHAN S. 2010. Anti-oxidant effect of gold nanoparticles restrains hyperglycemic conditions in diabetic mice. J Nanobiotechnology 8: 16., Chen et al. 2018aCHEN H, NG JPM & BISHOP DP. 2018a. Gold nanoparticles as cell regulators: beneficial effects of gold nanoparticles on the metabolic profile of mice with pre-existing obesity. J Nanobiotechnology 16: 88.). Scavenger action against ROS (Barathmanikanth et al. 2010BARATHMANIKANTH S, KALISHWARALAL K, SRIRAM M, PANDIAN S, YOUN HS, EOM S & GURUNATHAN S. 2010. Anti-oxidant effect of gold nanoparticles restrains hyperglycemic conditions in diabetic mice. J Nanobiotechnology 8: 16., Razzaq et al. 2016RAZZAQ H, SAIRA F, YAQUB A, QURESHI R, MUMTAZ M & SALEEMI S. 2016. Interaction of gold nanoparticles with free radicals and their role in enhancing the scavenging activity of ascorbic acid. J Photochem Photobiol B 161: 266-272.) and improvement of antioxidant defenses (Ko et al. 2020KO WC, SHIEH JM & WU WB. 2020. P38 MAPK and Nrf2 Activation Mediated Naked Gold Nanoparticle Induced Heme Oxygenase-1 Expression in Rat Aortic Vascular Smooth Muscle Cells. Arch Med Res 51: 388-396.) are among the mechanisms involved in the antioxidant action of AuNP. However, little is known about the effects of AuNP on oxidative stress induced by hypercholesterolemia in peripheral tissues. To verify the antioxidant effects of AuNP on peripheral tissues of hypercholesterolemic mice, we administered AuNP in mice by oral gavage every two days for eight weeks. Regarding the administration route, it is worth mentioning that AuNP is subjected to metabolization by the gastrointestinal system when administered by the oral route. The stomach’s gastric acid is likely to degrade the surface coatings of nanoparticles (Pan et al. 2007PAN Y, NEUSS S, LEIFERT A, FISCHLER M, WEN F, SIMIN ULRICH, SCHMID G, BRANDAU W & JAHNEN-DECHENT W. 2007. Size-dependent cytotoxicity of gold nanoparticles. Small 11: 1941-1949., Schleh et al. 2012SCHLEH C ET AL. 2012. Size and surface charge of gold nanoparticles determine absorption across intestinal barriers and accumulation in secondary target organs after oral administration. Nanotoxicology 6: 36-46.), resulting in the formation of ions from AuNP. However, the number of particles increased again in the gut, where the ions resulting from gastric acid digestion were deposited as particles in tissues. In this sense, the oral administration of AuNP with 28 nm in size to mice does not result in accumulation of AuNP in the stomach, but high levels of AuNP were easily found in the small intestine of the animals (Hillyer & Albrecht 2001HILLYER JF & ALBRECHT RM. 2001. Gastrointestinal persorption and tissue distribution of differently sized colloidal gold nanoparticles. J. Pharma Sci 12: 1927-1936.). This is because of the ability of colloidal AuNP to remain trapped in the gastrointestinal mucosa (Hillyer & Albrecht 2001HILLYER JF & ALBRECHT RM. 2001. Gastrointestinal persorption and tissue distribution of differently sized colloidal gold nanoparticles. J. Pharma Sci 12: 1927-1936.).

The choice of dose and administration period was made based on previous studies, which demonstrated that the administration of AuNP in a similar dose and every two days is safe and non-toxic to peripheral tissues (Chen et al. 2018bCHEN H ET AL. 2018b. Gold nanoparticles improve metabolic profile of mice fed a high-fat diet. J Nanobiotechnology 16: 11., Muller et al. 2017MULLER AP, FERREIRA GK, PIRES AJ, SILVEIRA GB, DE SOUZA DL, BRANDOLFI JA, DE SOUZA CT, PAULA MS & SILVEIRA PCL. 2017. Gold nanoparticles prevent cognitive deficits, oxidative stress and inflammation in a rat model of sporadic dementia of Alzheimer’s type. Mater Sci Eng C Mater Biol Appl 77: 476-483., Rodrigues et al. 2021RODRIGUES MS ET AL. 2021. Nanotechnology as a therapeutic strategy to prevent neuropsychomotor alterations associated with hypercholesterolemia. Colloids Surf B 201: 111608.). Using this safety administration strategy, we observed that AuNP treatment promotes redox homeostasis and displays important therapeutic effects in both cardiac and hepatic tissues, reducing ROS levels in the heart and increasing the SOD activity in the liver of hypercholesterolemic mice. On the other hand, long-term administration of AuNP in a higher dose (70 µg/kg) increased oxidative damage to the rat’s heart and liver (Ferreira et al. 2015FERREIRA GK ET AL. 2015. Gold nanoparticles alter parameters of oxidative stress and energy metabolism in organs of adult rats. Biochem Cell Biol 93: 548-557.) This finding illustrates the importance of studying the AuNP dose in its therapeutic effect on peripheral tissues, mainly in the liver and in the heart.

Indeed, the antioxidant effect of AuNP in the liver and heart has been described in the literature. AuNP treatment exerts important antioxidant activity through the downregulation of Kupffer cells and hepatic stellate cell activities in rat’s liver (de Carvalho et al. 2018DE CARVALHO TG ET AL. 2018. Spherical neutral gold nanoparticles improve anti-inflammatory response, oxidative stress and fibrosis in alcohol-methamphetamine-induced liver injury in rats. Int J Pharm 548: 1-14.). The AuNP treatment downregulated proinflammatory and improved lipid metabolic markers in the liver of obese mice (Chen et al. 2018aCHEN H, NG JPM & BISHOP DP. 2018a. Gold nanoparticles as cell regulators: beneficial effects of gold nanoparticles on the metabolic profile of mice with pre-existing obesity. J Nanobiotechnology 16: 88., b). In addition, diabetic mice treated with AuNP showed a significant decrease in ROS generation in the liver (Barathmanikanth et al. 2010BARATHMANIKANTH S, KALISHWARALAL K, SRIRAM M, PANDIAN S, YOUN HS, EOM S & GURUNATHAN S. 2010. Anti-oxidant effect of gold nanoparticles restrains hyperglycemic conditions in diabetic mice. J Nanobiotechnology 8: 16.). Reducing cellular damage markers to the liver and heart, restoring histopathological changes related to myocardial infarction, and reducing damage to the heart’s DNA in mice are other effects related to the AuNP treatment in peripheral tissues (Ibrar et al. 2018IBRAR M, KHAN MA & ABDULLAH IMRAN M. 2018. Evaluation of Paeonia emodi and its gold nanoparticles for cardioprotective and antihyperlipidemic potentials. J Photochem Photobiol B 189: 5-13.). Also, AuNP significantly improved the antioxidant activity of GSH and ameliorated the redox and inflammatory profile on the rat’s heart (Abdelhalim et al. 2015ABDELHALIM MA, AL-AYED MS & MOUSSA AS. 2015. The effects of intraperitoneal administration of gold nanoparticles size and exposure duration on oxidative and antioxidants levels in various rat organs. Pak J Pharm Sci 28: 705-712., Tartuce et al. 2020TARTUCE LP ET AL. 2020. 2-methoxy-isobutyl-isonitrile-conjugated gold nanoparticles improves redox and inflammatory profile in infarcted rats. Colloids Surf B Biointerfaces 192: 111012.). These findings contrast in parts with the data obtained in our study, in which we do not observe the effect of AuNP treatment on GSH levels in the cardiac tissue of hypercholesterolemic mice. We hypothesized that these contrasting effects on GSH levels between our data and the result obtained by Abdelhalim et al. (2015)ABDELHALIM MA, AL-AYED MS & MOUSSA AS. 2015. The effects of intraperitoneal administration of gold nanoparticles size and exposure duration on oxidative and antioxidants levels in various rat organs. Pak J Pharm Sci 28: 705-712. are due to AuNP’s size and administration route differences. In other words, the AuNP with 10 nm in size and the intraperitoneal administration performed by Abdelhalim et al. (2015)ABDELHALIM MA, AL-AYED MS & MOUSSA AS. 2015. The effects of intraperitoneal administration of gold nanoparticles size and exposure duration on oxidative and antioxidants levels in various rat organs. Pak J Pharm Sci 28: 705-712. and colleges facilitates the visualization of the antioxidant effect of AuNP in the cardiac tissue of Wistar-Kyoto rats. This is because AuNP smaller in size tends to cross the corporal barriers easily and could be found in more significant amounts in tissues (Hillyer & Albrecht 2001HILLYER JF & ALBRECHT RM. 2001. Gastrointestinal persorption and tissue distribution of differently sized colloidal gold nanoparticles. J. Pharma Sci 12: 1927-1936.). Also, it was shown that AuNPs administration, when performed by oral route, only a small amount was absorbed by the tissues, whereas the intraperitoneal administration results in greater amounts of AuNP in tissues (Zhang et al. 2010ZHANG XD, WU HY, WU D, WANG YY, CHANG JH, ZHAI ZB, MENG AM, LIU PX, ZHANG LA & FAN FY. 2010. Toxicologic effects of gold nanoparticles in vivo by different administration routes. Int J Nanomedicine 5: 771-781.).

Taken together, our data show that diet-induced hypercholesterolemia significantly altered the redox balance in the liver and heart in a process that favors oxidative damage. The treatment of hypercholesterolemic mice with AuNP promoted the redox balance in both cardiac and hepatic tissues, increasing the antioxidant defense and neutralizing the production of reactive species in these tissues (Figure 4). It is worth mentioning that our study is the first to demonstrate a significant antioxidant effect of AuNP in the peripheral tissues, mainly in the heart, of hypercholesterolemic mice. In this sense, additional biological studies must be performed to elucidate better the mechanisms involved in the antioxidant effect of AuNP in peripheral oxidative stress related to hypercholesterolemia.

Figure 4
The illustration summarizes the effects of high cholesterol diet exposure and AuNP treatment on metabolic and oxidative stress parameters in the liver and heart of mice. Briefly, animals fed a high cholesterol diet exhibited high plasma cholesterol levels, i.e., hypercholesterolemia, which was not affected by AuNPs treatment. Also, hypercholesterolemia caused an imbalance of the redox system in the liver and the heart in a process that favors oxidative damage. AuNP treatment promoted redox system balance in both liver and heart, increasing antioxidant defense and reducing ROS production.

ACKNOWLEDGMENTS

The authors acknowledge funding from the grant FAPESC/CNPq 16802017 06/2016. The authors would also like to thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Fundação de Amparo à Pesquisa e Inovação do Estado de Santa Catarina (FAPESC) Universidade do Extremo Sul Catarinense (UNESC), and INCT (Instituto Nacional de Ciência e Tecnologia) for the financial support and facilities in carrying out this study.

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Publication Dates

Publication in this collection
16 Dec 2022
Date of issue
2022

History

Received
6 Aug 2021
Accepted
24 Nov 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABDELHALIM MA, AL-AYED MS & MOUSSA AS. 2015. The effects of intraperitoneal administration of gold nanoparticles size and exposure duration on oxidative and antioxidants levels in various rat organs. Pak J Pharm Sci 28: 705-712.

[2] ALSAAD AM, MOHANY M, ALMALKI MS, ALMUTHAM I, ALAHMARI A, ALSULAMAIN M & AL-REJAIE S. 2020. Baicalein Neutralizes Hypercholesterolemia-Induced Aggravation of Oxidative Injury in Rats. Int J Med Sci 17: 1156-1166.

[3] AMIN KA & ABD EL-TWAB TM. 2009. Oxidative markers, nitric oxide and homocysteine alteration in hypercholesterolimic rats: role of atorvastatine and cinnamon. Int J Clin Exp Med 2: 254-265.

[4] ASHRY NA, ABDЕLAZIZ RR & SUDDЕK GM. 2020. The potential effect of imatinib against hypercholesterolemia induced atherosclerosis, endothelial dysfunction and hepatic injury in rabbits. Life Sci 243: 117275.

[5] BANNISTER JV & CALABRESE L. 1987. Assays for superoxide dismutase. Methods Biochem Anal 32: 279-312.

[6] BARATHMANIKANTH S, KALISHWARALAL K, SRIRAM M, PANDIAN S, YOUN HS, EOM S & GURUNATHAN S. 2010. Anti-oxidant effect of gold nanoparticles restrains hyperglycemic conditions in diabetic mice. J Nanobiotechnology 8: 16.

[7] BIRBEN E, SAHINER UM, SACKESEN C, ERZURUM S & KALAYCI O. 2012. Oxidative stress and antioxidant defense. World Allergy Organ J 5: 9-19.

[8] BURTON GJ & JAUNIAUX E. 2011. Oxidative stress. Best Pract Res Clin Obstet Gynaecol 25: 287-299.

[9] BYRNE CD & TARGHER G. 2015 NAFLD: a multisystem disease. J Hepato 62: S47-S64.

[10] CHAE SY, LEE M, KIM SW & BAE YH. 2004. Protection of insulin secreting cells from nitric oxide induced cellular damage by crosslinked hemoglobin. Biomaterials 25: 843-850.

[11] CHEN H, NG JPM & BISHOP DP. 2018a. Gold nanoparticles as cell regulators: beneficial effects of gold nanoparticles on the metabolic profile of mice with pre-existing obesity. J Nanobiotechnology 16: 88.

[12] CHEN H ET AL. 2018b. Gold nanoparticles improve metabolic profile of mice fed a high-fat diet. J Nanobiotechnology 16: 11.

[13] CHTOUROU Y, SLIMA AB, MAKNI M, GDOURA R & FETOUI H. 2015. Naringenin protects cardiac hypercholesterolemia-induced oxidative stress and subsequent necroptosis in rats. Pharmacol Rep 67: 1090-1097.

[14] CHUNG WH. 2017. Unraveling new functions of superoxide dismutase using yeast model system: Beyond its conventional role in superoxide radical scavenging. J Microbiol 55: 409-416.

[15] CSONKA C ET AL. 2017. Isolated hypercholesterolemia leads to steatosis in the liver without affecting the pancreas. Lipids Health Dis 16: 144.

[16] CSONKA C, SÁRKÖZY M & PIPICZ M. 2016. Modulation of Hypercholesterolemia-Induced Oxidative/Nitrative Stress in the Heart. Oxidative Medicine and Cellular Longevity 2016: 3863726.

[17] CSONT T ET AL. 2007. Hypercholesterolemia increases myocardial oxidative and nitrosative stress thereby leading to cardiac dysfunction in apoB-100 transgenic mice. Cardiovasc Res 76: 100-109.

[18] DE CARVALHO TG ET AL. 2018. Spherical neutral gold nanoparticles improve anti-inflammatory response, oxidative stress and fibrosis in alcohol-methamphetamine-induced liver injury in rats. Int J Pharm 548: 1-14.

[19] DELLA VECHIA IC ET AL. 2020. Comparative cytotoxic effect of citrate-capped gold nanoparticles with different sizes on noncancerous and cancerous cell lines. J Nanopart Res 22: 133.

[20] DE OLIVEIRA J, HORT MA, MOREIRA EL, GLASER V, RIBEIRO-DO-VALLE RM, PREDIGER RD, FARINA M, LATINI A & DE BEM AF. 2011. Positive correlation between elevated plasma cholesterol levels and cognitive impairments in LDL receptor knockout mice: relevance of cortico-cerebral mitochondrial dysfunction and oxidative stress. Neuroscience 197: 99-106.

[21] DE OLIVEIRA J, MOREIRA EL, DOS SANTOS D, PIERMARTIRI T, DUTRA R, PINTON S, TASCA C, FARINA M, PREDIGER R & DE BEM AF. 2014. Increased susceptibility to amyloid-β-induced neurotoxicity in mice lacking the low-density lipoprotein receptor. J Alzheimers Dis 41: 43-60.

[22] DEORI M, DEVI D, KUMARI S, HAZARIKA A, KALITA H, SARMA R & DEVI R. 2016. Antioxidant Effect of Sericin in Brain and Peripheral Tissues of Oxidative Stress Induced Hypercholesterolemic Rats. Front Pharmacol 7: 319.

[23] DE SOUZA RM, DE SOUZA L, MACHADO AE, ALVES AC, RODRIGUES FS, AGUIAR JR AS, DOS SANTOS ARS, DE BEM AF & MOREIRA ELG. 2019. Behavioural, metabolic and neurochemical effects of environmental enrichment in high-fat cholesterol-enriched diet-fed mice. Behav Brain Res 359: 648-656.

[24] ELAHI M & MATATA B. 2015. Blood-dependent redox activity during extracorporeal circulation in health and disease. The Cardiology 1: 156-157.

[25] ENRÍQUEZ-CORTINA C, BELLO-MONROY O & ROSALES-CRUZ P. 2017. Cholesterol overload in the liver aggravates oxidative stress-mediated DNA damage and accelerates hepatocarcinogenesis. Oncotarget 8: 104136-104148.

[26] FERREIRA GK ET AL. 2015. Gold nanoparticles alter parameters of oxidative stress and energy metabolism in organs of adult rats. Biochem Cell Biol 93: 548-557.

[27] GAUCHER C, BOUDIER A, BONETTI J, CLAROT I, LEROY P & PARENT M. 2018. Glutathione: Antioxidant Properties Dedicated to Nanotechnologies. Antioxidants (Basel) 7: 62.

[28] GIDDING SS & ALLEN NB. 2019. Cholesterol and Atherosclerotic Cardiovascular Disease: A Lifelong Problem. J Am Heart Assoc 8: e012924.

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