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Hepatic Expression of Adiponectin Receptors Increases with Non
Hepatic Expression of Adiponectin Receptors Increases with Non-alcoholic Fatty Liver Disease Progression in Morbid Obesity in Correlation with Glutathione Peroxidase 1 Obesity Surgery The Journal of Metabolic Surgery and Allied Care ISSN 0960-8923 Volume 21 Number 4 OBES SURG (2011) 21:492-500 DOI 10.1007/ s11695-010-0353-2 1 23 Your article is protected by copyright and all rights are held exclusively by Springer Science + Business Media, LLC. This e-offprint is for personal use only and shall not be selfarchived in electronic repositories. If you wish to self-archive your work, please use the accepted author’s version for posting to your own website or your institution’s repository. You may further deposit the accepted author’s version on a funder’s repository at a funder’s request, provided it is not made publicly available until 12 months after publication. 1 23 Author's personal copy OBES SURG (2011) 21:492–500 DOI 10.1007/s11695-010-0353-2 CLINICAL RESEARCH Hepatic Expression of Adiponectin Receptors Increases with Non-alcoholic Fatty Liver Disease Progression in Morbid Obesity in Correlation with Glutathione Peroxidase 1 Angel Carazo & Josefa León & Jorge Casado & Ana Gila & Sergio Delgado & Ana Martín & Laura Sanjuan & Trinidad Caballero & Jose Antonio Muñoz & Rosa Quiles & Angeles Ruiz-Extremera & Luis Miguel Alcázar & Javier Salmerón Published online: 17 January 2011 # Springer Science+Business Media, LLC 2011 Abstract Background The prevalence of non-alcoholic fatty liver disease (NAFLD) in obesity is very high. The role of adiponectin receptors in NAFLD progression remains still unclear. We speculate that changes in the hepatic expression levels of the two adiponectin receptors may be associated with the expression of oxidative stress-related genes. Methods We studied 60 morbidly obese patients with NAFLD, who underwent liver biopsy at the time of bariatric surgery. We measured the hepatic messenger-RNA concentration of adiponectin receptors (ADIPOR1 and ADIPOR2), glutathione peroxidase 1 (GPx1), glutathione reductase (GRd) and inducible oxide nitric synthase. Additionally, biochemical parameters and oxidative stress markers were determined in A. Carazo : J. León : J. Casado : A. Gila : A. Martín : L. Sanjuan : J. A. Muñoz : R. Quiles : A. Ruiz-Extremera : L. M. Alcázar : J. Salmerón Research Unit, San Cecilio University Hospital, Av de Madrid s/n, 18012 Granada, Spain J. León : A. Gila : T. Caballero : R. Quiles : A. Ruiz-Extremera : L. M. Alcázar : J. Salmerón Centro de Investigación Biomédica en Red de Enfermedades Hepáticas y Digestivas (Ciberehd), Granada, Spain A. Carazo (*) : S. Delgado Surgery Unit, San Cecilio University Hospital, Granada, Spain e-mail: [email protected] A. Carazo : T. Caballero Pathological Anatomy Unit, San Cecilio University Hospital, Granada, Spain blood samples. According to the Kleiner score, the patients were divided into two groups: group 1 (25 patients without steatohepatitis) and group 2 (25 patients with probable steatohepatitis and ten patients with steatohepatitis). Results The messenger-RNA concentration of all genes analysed in the study was higher among the patients in group 2. However, no differences in blood oxidative stress markers were observed. Strong correlations were found among the expression levels of ADIPOR1, ADIPOR2 and GPx1. The multivariate analysis showed that the only independent variable associated with NAFLD progression was the increase in GPx1 expression levels. Conclusions NAFLD progression in morbid obesity is associated with increase in hepatic adiponectin receptor and oxidative stress-related genes. The linear correlations suggest that ADIPOR1, ADIPOR2 and GPx1 share key molecular factors in the regulation of the genetic expressions. Keywords Non-alcoholic fatty liver disease . Non-alcoholic steatohepatitis . Morbid obesity . Adiponectin . Adiponectin receptors . Glutathione peroxidase . Glutathione reductase . Inducible oxide nitrite synthase Abbreviations BMI Body mass index NAFLD Non-alcoholic fatty liver disease NASH Non-alcoholic steatohepatitis ADIPOR1 Adiponectin receptor 1 ADIPOR2 Adiponectin receptor 2 GPx1 Glutathione peroxidase 1 GRd Glutathione reductase Author's personal copy OBES SURG (2011) 21:492–500 iNOS LDL HDL ALT AST GGT HOMA-IR GSH GSSG PCR Ct PPIA RPS13 bp Inducible oxide nitrite synthase Low-density lipoprotein High-density lipoprotein Alanine aminotransferase Aspartate aminotransferase Gamma glutamiltransferase Homeostasis model assessment Reduced glutathione Oxidised glutathione Polymerase chain reaction Threshold cycle Peptidylprolyl isomerase A Ribosomal protein S13 Base pairs Introduction The incidence of obesity is increasing dramatically and, at present, obesity is considered as a public health problem. The most important pathological consequences are nonalcoholic fatty liver disease (NAFLD), type 2 diabetes mellitus and cardiovascular disease [1]. NAFLD includes a spectrum of hepatic abnormalities ranging from hepatic steatosis to more severe pathologies like non-alcoholic steatohepatitis (NASH) and cirrhosis. NAFLD prevalence increases with adiposity up to 85% in morbid obesity, defined as having a body mass index (BMI) of greater than 40 kg/m2 [2]. Moreover, the exact prevalence of NASH in morbidly obese patients is unknown and could change considerably depending on the biopsy heterogeneity [3] and the histological definition of NASH [4]. Currently, the “two-hit (or multiple hit) hypothesis” is broadly accepted to explain the progression of NAFLD [5]. The accumulation of lipids in the cytoplasm of hepatocytes (the first hit) triggers a series of cytotoxic events (secondary hits) which culminate in steatohepatitis. In this context, insulin and leptin resistances, free radical over-production, excess of visceral fat and adipose tissue and liver inflammation are involved in the origin and progression of NAFLD [6–10]. Adiponectin is a hormone that is expressed mainly by adipocytes and which has anti-inflammatory and insulinsensitising effects. Decreasing levels of adiponectin during obesity have been related with insulin resistance, liver steatosis and other features of the metabolic syndrome such as dyslipidaemia and hypertension [11]. Regarding the role of hepatic adiponectin receptors (ADIPOR1 and ADIPOR2 isoforms) in the progression of NAFLD, contradictory results have been published. On the one hand, falls in liver ADIPOR2 levels in patients with NASH, compared with controls, have been reported [12]. But, other studies have 493 found no such variations [13], or increases in both receptors [14] or increases only in the ADIPOR2 isoform [15, 16]. Glutathione peroxidase 1 (GPx1) is a seleno-protein that reduces hydroperoxides by means of glutathione. Its role is mainly that of an antioxidant. GPx1 knockout mice tolerate moderate oxidative stress [17], but are highly susceptible to severe oxidative damage [18]. Moreover, GPx1 knockout mice increase insulin sensitivity [19]. In contrast, GPx1 overexpressing mice are more resistant to acute oxidative stress and develop insulin resistance and obesity [20]. Although an excess in oxidative damage is associated with the pathology of many human diseases, a growing body of evidence shows that low levels of reactive oxygen and nitrogen species are required for normal cellular functioning and intracellular signalling [19, 21]. In this context, a recent study reported that ADIPOR2 promoter is affected by endoplasmic oxidative stress [22]. Another recent study reported that muscle-specific disruption of ADIPOR1 decreased muscle oxidative stress-detoxifying enzymes and mitochondrial content [23]. In addition, ADIPOR2 overexpression in a model of diabetic and obese mice increased the expression of hepatic antioxidant enzymes [24]. These precedents suggest a link between adiponectin receptors and oxidative stress pathways. We hypothesised that changes in the hepatic expression of adiponectin receptors during the NAFLD progression may be associated with the expression of oxidative stress-related genes. Accordingly, we studied 60 morbidly obese patients with NAFLD, who underwent a liver biopsy at the time of bariatric surgery. The grade of NAFLD progression was evaluated according to the Kleiner score [25], and the systemic oxidative stress was evaluated by measuring representative blood markers. Moreover, in a biopsy sample, we studied the level of expression of adiponectin receptors, GPx1, glutathione reductase (GRd) and inducible oxide nitric synthase (iNOS). Materials and Methods Subjects The patient cohort included 60 morbidly obese subjects who underwent bariatric surgery at the San Cecilio University Hospital (Granada, Spain). Exclusion criteria for the study included primary liver disorders other than fatty liver that could account for steatosis, including alpha1-antitrypsin deficiency, infectious hepatitis or Wilson’s disease, which were identified by specific disease markers. The maximal alcohol consumption of the study participants was 30 g per week in men and 20 g in women. The ethics committee of the hospital approved the study, and all subjects provided written informed consent. Author's personal copy 494 Biological Samples Liver biopsies were obtained at the moment of bariatric surgery. Blood samples were collected before the surgery and after 10 h fasting. Additionally, 1 year after the bariatric surgery, blood samples but not liver biopsies were collected. For biochemical parameter determinations, blood samples were processed and analysed by routine methods within 24 h at the Clinical Analysis Laboratory of the San Cecilio University Hospital (Granada, Spain). For each patient, glucose (milligrammes per decilitre), insulin (microunits per millilitre), triglycerides (milligrammes per decilitre), total cholesterol (milligrammes per decilitre), LDL cholesterol (milligrammes per decilitre), HDL cholesterol (milligrammes per decilitre), alanine aminotransferase (ALT; units per litre), aspartate aminotransferase (AST; units per litre) and GGT (units per litre) were determined. The model assessment (HOMA-IR) index was calculated to evaluate the insulin resistance. Adiponectin Determinations Adiponectin plasma levels were measured using the LINCOplex kit with the Luminex 100 Integrated System 2.3 software on the Bio-PlexTM 200 System (BIO-RAD). The assays were performed according to the manufacturer’s instructions. Determination of Oxidative Stress Parameters Nitrite levels Plasma samples were deproteinised, and supernatants were used to measure the amount of nitrite, via the Griess reaction at 550 nm in a microplate reader (TRIAD series, Dynex Technologies). Nitrite concentrations were calculated according to a standard curve and expressed in nanomoles per millilitre. GPx, GRd activities The erythrocytes were lysed, and supernatants were used. Glutathione peroxidase (GPx) and glutathione reductase (GRd) activities were measured following the oxidation of NADPH for 3 min at 340 nm in a UV-spectrophotometer (Biomate, Thermo Spectronic). The activities of both enzymes are expressed in nanomoles per milligramme haemoglobin (HB). GSH and GSSG assays The erythrocytes were lysed and the supernatants incubated with ophthalaldehyde. The fluorescence of the samples was then measured in a plate-reader spectrofluorometer (TRIAD Series, Dynex Technologies). A standard curve of known reduced glutathione (GSH) concentration was prepared and processed with the samples. For oxidised glutathione (GSSG) concentration measurement, the supernatants were pre-incubated with N-ethylmaleimide and OBES SURG (2011) 21:492–500 then alkalinized with NaOH. The fluorescence was measured, and the GSSG concentrations were calculated according to a standard curve. The levels of GSH and GSSG are expressed in nanomoles per milligramme haemoglobin. Anatomopathological Study All biopsies were evaluated by a single experienced pathologist using the scoring system validated by Kleiner et al. [25]. This histology scoring system quantifies necroinflammatory and steatotic changes (steatosis, lobular inflammation and ballooning) and produces NAFLD activity scores that range between 0 and 8. Scores greater or equal to 5 were diagnosed as NASH; scores of 3 and 4 were classified as probable NASH, while scores of 1 and 2 were diagnosed as not NASH. Hepatic Gene Expression Total RNA was purified in a fraction of each liver biopsy. Five hundred nanogrammes of RNA was retrotranscribed to cDNA using the qScript Flex cDNA Synthesis Kit (Quanta) according to the manufacturer’s instructions. The quantification of mRNA concentration for each gene was performed in a fraction of cDNA volume by Real-time PCR (Mx3000P Stratagene) using the SYBR green supermix (Quanta). The primers (Table 1) were tested previously to evaluate their specificity and sensitivity. Unspecific amplifications were not detected in the test. The annealing temperature (specific for each gene) ranged from 58°C to 62°C. Each determination was carried out in duplicate, and the mathematical relation between the threshold cycle (Ct) level and the initial DNA quantity was evaluated by a standard curve. Finally, the results were normalised using the expression level of two hepatic housekeeping genes: PPIA and RPS13 [26, 27]. For each gene, the mRNA concentration was expressed in femtogrammes of mRNA by picogrammes (fg of mRNA/pg) of housekeeping mRNAs average. Statistical Studies Statistical analyses were performed using the Statistical Package for Social Sciences (SPSS-12.0, SPSS Inc., Chicago, IL). The results are reported as mean±standard error mean. Unvaried unadjusted analyses were performed with the independent-samples t test to compare normally distributed variables, while the Mann–Whitney U test was used for variables not normally distributed. The linear correlations were calculated by Pearson’s correlation coefficient. The criterion for statistical significance was P<0.05. Author's personal copy OBES SURG (2011) 21:492–500 Table 1 Primer sequences for the amplification of cDNA by real-time PCR 495 Gene Sense primer Antisense primer Amplicon ADIPOR1 ADIPOR2 GPx1 GRd iNOS PPIA RPS13 ccatgcactttactatcgctgagggctttg ttcctaccttgcactatgtcatctcggagg tggacaattgcgccatgtgtgctgctc aacaacatcccaactgtggtcttcagccac gatgaggaccacatctaccaggag ccatggcaaatgctggacccaacacaaatg ggtgttgcacaagtacgttttgtgacaggc ctgaaggttggagactccatagaagtggac gaaacgaaactcctggaggtttgagacacc tgatgcccaaactggttgcacgggaag gtagggtgaatggcgactgtgttgtcaaag ccataggaaaagactgcaccgaag tcctgagctacagaaggaatgatctggtgg tcatatttccaattgggagggaggactcgc 233 251 265 314 284 256 251 Results Baseline Characteristics Sixty morbidly obese patients with NAFLD were included in this study (18 men and 42 women). According to the anatomopathological Kleiner score, 25 of these patients were without NASH, 25 were with probable NASH, and ten were with NASH. The patients were divided into two groups, 25 patients without NASH (group 1) and 35 patients with probable NASH or with NASH (group 2). Table 2 shows BMI, blood biochemical parameters and plasmatic levels for adiponectin in both groups of patients. In group 2, significant increases were found only for AST and ALT. Plasmatic Oxidative Stress Parameters Table 3 shows plasma nitrite concentration, erythrocyte glutathione peroxidase and reductase specific activity and erythrocyte concentration of oxidised and reduced glutathione in relation to the progression of NAFLD. These variables are representative markers of systemic oxidative stress. In this respect, there were no significant differences between the two groups of patients. Hepatic Gene Expression and Linear Correlations Table 4 shows the hepatic mRNA concentrations of ADIPOR1, ADIPOR2, GPx, GRd and iNOS in relation to the progression of NAFLD. The mean expression level of all these genes increased significantly in the group 2 patients. Concerning the relative concentration of adiponectin receptor isoforms, ADIPOR2 was significantly more abundant than ADIPOR1 in group 2 (P<0.000) but not in group 1. We also analysed the correlations between the hepatic gene expressions in all patients and, separately, in each group of patients. These correlations are represented in Figs. 1 and 2. Note that the iNOS levels were previously transformed by logarithmic function to normalise the distribution. Interestingly, we found a good linear correla- bp bp bp bp bp bp bp tion between the expressions of both adiponectin receptors and GPx1 (Fig. 1). These correlations persisted even when patients were classified by the Kleiner score. ADIPOR1 levels showed a weak correlation with GRd and iNOS expressions only for all patients (Fig. 1). Moreover, ADIPOR2 levels correlated more strongly with GRd and iNOS expressions for all patients and for group 1 but not for group 2 (Fig. 1). There was also a linear correlation between the two adiponectin receptors for all patients and for both groups of patients (Fig. 2). Furthermore, GPx1 correlated with GRd expression for all patients and for group 1 but not for group 2 patients (Fig. 2). Multivariate Analysis The multivariate analysis showed that the only independent variable associated with the progression of NAFLD was an increase in the GPx1 expression level (OR, 1.095; 95% CI 1.019–1.178; P=0.014). BMI and Plasmatic Level Variations After Bariatric Surgery Table 5 shows BMI, biochemical parameters, leptin and adiponectin plasmatic levels and systemic oxidative stress markers, before bariatric surgery and 1 year after the surgery, in 42 patients (16 from group 1 and 26 from group 2). Only significant differences are represented. As a result of the great loss in body fat mass, the majority of parameters measured in blood samples became normal. There was also observed to be an increase in adiponectin level and changes in two systemic oxidative stress markers. Discussion At present, the two-hit hypothesis is broadly accepted to explain the origin and progression of NAFLD during obesity [5]. Several main processes have been implicated in the pathology of NAFLD, such as insulin resistance, leptin resistance, excess of visceral fat, free radical overproduction or reduced levels of adiponectin [6–11]. Nevertheless, the precise molecular mechanisms that induce Author's personal copy 496 Table 2 Patient characteristics Group 1, 25 patients without NASH. Group 2, 35 patients with probable NASH and NASH. Data are means±SEM. Significant P values are depicted in bold OBES SURG (2011) 21:492–500 Characteristics Group 1 Group 2 P Value Age (years) Gender: men, n (%); women, n (%) BMI (kg/m2) AST (U/l) ALT (U/l) GGT (U/l) Total-cholesterol (mg/dl) LDL-cholesterol (mg/dl) HDL-cholesterol (mg/dl) Triglycerides (mg/dl) Glucose (mg/dl) Insulin HOMA-IR Adiponectin (ng/ml) 43.5±2.4 8 (32.0%); 17 (68.0%) 50.8±1.8 27.6±4.1 24.9±4.1 37.3±8.8 156.9±6.1 89.4±6.2 40.7±2.2 151.5±18.4 128.4±7.9 12.7±2.2 3.6±0.5 36.8±6.8 44.5±1.6 10 (28.5%); 25 (71.5%) 52.2±1.3 41.5±3.5 34.4±2.4 37.8±4.9 174.3±9.3 100.1±7.6 41.2±3.1 200.3±25.8 139.5±9.0 12.6±1.3 4.4±0.5 35.5±5.8 0.640 0.783 0.520 0.018 0.038 0.957 0.154 0.305 0.904 0.161 0.382 0.967 0.277 0.885 the evolution from a liver with steatosis to one with steatohepatitis remain unclear. Another poorly understood aspect is the role of adiponectin receptors during NAFLD progression. Two papers have reported that the abrogation or over-expression of adiponectin receptors in mice is associated with a respective decrease or increase in oxidative stress-detoxifying enzymes [23, 24]. The aim of our study was to analyse, in a cohort of morbidly obese patients with NAFLD, the hepatic expression level of adiponectin receptors and oxidative stress-related genes and to analyse these expression levels in the context of NAFLD progression. We observed changes in the expression levels of all genes analysed, in relation to NAFLD progression (Table 4) but the blood parameters showed differences only in ALT and AST levels (Tables 2 and 3). In our morbidly obese cohort, the liver injury was probably not sufficiently advanced to significantly change the blood parameters, but the emergence of NASH was enough to modify the hepatic gene expression profile. In this article, we report an increase in the hepatic expression levels of both adiponectin receptors in relation to NAFLD progression in morbid obesity. In addition, we report a good correlation between the hepatic expression levels of ADIPOR1 and ADIPOR2, suggesting the existence of common factors in the genetic regulation of both receptors. Furthermore, in the group 2 patients, the relative concentration of ADIPOR2 increased with respect to that of ADIPOR1 (Table 4). This suggests that the molecular mechanisms implicated in the adiponectin receptor overexpression, during NAFLD progression, preferably stimulate the ADIPOR2 gene. Contradictory data have been published concerning the role of hepatic adiponectin receptor expression during the development of NAFLD in human obese cohorts. Decreases in hepatic ADIPOR2 mRNA levels in relation to NAFLD development have been reported in two articles. ADIPOR2 decreased in morbidly obese patients with NASH respect to morbidly obese controls with simple steatosis [12] and in moderately obese patients with NAFLD with respect to lean persons without steatosis [28]. However, other articles have reported increases in adiponectin receptors in obese patients with NASH [14–16]. Our results are in agreement with the latter articles. In our opinion, these Table 3 Blood oxidative stress markers Blood oxidative stress markers Group 1 Group 2 P Value Nitrite (nmol/mL) GPx specific activity GRd specific activity Total-gluthatione (nmol/mg HB) GSH (nmol/mg HB) GSSG (nmol/mg HB) 8.4±1.0 31.0±2.2 2.4±0.1 4.0±1.6 2.1±0.3 1.9±0.2 10.0±0.7 27.3±1.2 2.3±0.1 4.9±1.8 2.8±0.3 2.2±0.1 0.181 0.118 0.500 0.722 0.114 0.151 Group 1, 25 patients without NASH. Group 2, 35 patients with probable NASH and NASH. Data are means±SEM Table 4 Hepatic mRNA concentration means Hepatic mRNA concentration Group 1 Group 2 P Value ADIPOR1 ADIPOR2 GPx1 GRd iNOS 14.4±1.2 17.2±2.2 47.7±3.3 15.7±1.9 22.5±8.4 21.1±0.9 30.3±1.4 76.7±2.9 20.6±0.8 51.2±7.9 <0.000 <0.000 <0.000 0.024 0.015 Group 1, 25 patients without NASH. Group 2, 35 patients with probable NASH and NASH. Data are means±SEM Author's personal copy OBES SURG (2011) 21:492–500 497 Fig. 1 Correlations between the hepatic mRNA levels of adiponectin receptors and the oxidative stress-related genes. Closed points represent patients without NASH (group 1). Open points represent patients with probable NASH or NASH (group 2). Only the Pearson’s coefficient and the linear fitting of significant correlations are shown. RT Pearson’s coefficient of total patients, R1 Pearson’s coefficient of group 1, R2 Pearson’s coefficient of group 2. *P<0.050, **P<0.010, ***P<0.001 contradictory data are a consequence of biological differences between the patient cohorts and also result from methodological differences in measuring the mRNA concentration. The selection of an adequate housekeeping gene for the normalisation of data may be a significant factor in determining the quality of results [26, 27]. A recent paper reported increases in hepatic ADIPOR1 and ADIPOR2 mRNA levels in obese patients with Fig. 2 Correlations between the hepatic mRNA levels of both adiponectin receptors and between GPx1 and Grd. Closed points represent patients without NASH (group 1). Open points represent patients with probable NASH or NASH (group 2). Only the Pearson’s coefficient and the linear fitting of significant correlations are shown. RT Pearson’s coefficient of total patients, R1 Pearson’s coefficient of group 1, R2 Pearson’s coefficient of group 2. *P<0.050, **P<0.010, ***P<0.001 Author's personal copy 498 Table 5 BMI and plasmatic levels before the bariatric surgery and one year after the surgery Only significant differences are shown. N=42 patients. Data are means±SEM OBES SURG (2011) 21:492–500 BMI (kg/m2) AST (U/L) ALT (U/L) GGT (U/L) Total-cholesterol (mg/dl) HDL-cholesterol (mg/dl) Triglycerides (mg/dl) Glucose (mg/dl) Glucose (mg/dl) Insulin HOMA-IR Adiponectin (μg/mL) Total-glutathione (nmol/mg HB) GPx specific activity elevated HOMA-IR (mean value, 7.3) with respect to obese patients with a reduced HOMA-IR (mean value, 1.7) [29], suggesting a certain link between systemic insulin resistance and the hepatic expression of adiponectin receptors. Moreover, in our cohort, there were not enough patients at the extremes of the HOMA-IR to perform a study of this kind, and there were no significant differences in relation to the HOMA-index or the fasting insulin level. Free radical over-production has been related with the pathology of NAFLD [10]. Oxidative stress is not only a cause of cellular damage but is also a symptom of dysfunction in the mitochondrion and the endoplasmic reticulum [30, 31]. Mitochondrial dysfunction during obesity is closely related to hypercaloric diets [31]. Oxidative stress triggers inflammatory pathways [32] and, reciprocally, is generated by the inflammatory process. In fact, iNOS activity is a major source of the nitric oxide produced by macrophages during inflammation and is one of the most important enzymes involved in the oxidative stress pathway [33]. In animal models, iNOS plays a crucial role in the development of NASH [34]. Moreover, iNOS polymorphisms have been related with the risk of NAFLD in a human cohort [35]. To the best of our knowledge, our study provides the first report of an increase in hepatic iNOS expression levels with NAFLD progression in morbid obesity (Table 4). Our results suggest that, in our patient cohort, NAFLD progression is accompanied by free radical over-production in the liver. In this context, the increase in GRd and GPx1 expression in group 2 (Table 4) could be interpreted as a stimulation of the stressdetoxifying mechanism in response to a deterioration in the liver redox status. Nevertheless, systemic oxidative stress markers did not present significant differences with NAFLD progression (Table 3), and at 1 year after the bariatric surgery, only Before After P Value 51.5±1.3 29.8±3.3 31.0±3.1 37.7±8.0 183.1±8.9 36.0±1.6 182.1±18.1 119.0±6.5 119.0±6.5 10.6±1.0 3.4±0.4 39.9±6.0 4.9±0.5 27.9±2.0 31.3±0.9 20.4±1.0 19.3±1.5 17.5±2.1 137.5±6.0 50.6±2.3 88.0±6.6 104.3±2.5 104.3±21.5 4.9±0.6 1.0±0.1 60.0±2.1 6.3±0.5 22.5±1.3 <0.000 0.007 0.001 <0.000 <0.000 <0.000 <0.000 0.037 0.001 0.008 0.001 0.002 0.051 0.026 moderate change was detected in systemic oxidative stress markers (Table 5). Our results suggest that, in our cohort, the increase in hepatic oxidative stress-related genes during NAFLD progression had a slight effect on systemic oxidative stress markers, which are probably strongly influenced by other tissues and organs, such as white adipose tissue. In accordance with our initial hypothesis, correlations were found between the expression levels of both adiponectin receptors and the oxidative stress-related genes measured in the study: GPx1, GRd and iNOS (Fig. 1). Interestingly, we recorded a strong correlation between both adiponectin receptors and GPx1, reaching a maximum for ADIPOR1 among the patients in group 1 (Pearson’s coefficient of 0.828). These data suggest that ADIPOR1, ADIPOR2 and GPx1 share key molecular factors in the regulation of the genetic expressions. Moreover, the Pearson’s coefficient of these correlations decreased in the group 2 patients. The onset of liver inflammation probably causes an alteration in different cellular pathways, which impacts on the control of many genetic expressions. In addition, the multivariate analysis showed that the only independent factor for NAFLD progression was the increase in GPx1 liver expression. This finding highlights the weight of GPx1 gene induction in the mechanisms that may control the progression of NAFLD. Adiponectin receptors were initially described in 2003 [36]. T-cadherin has also been proposed as a third adiponectin receptor [37], but its biological relevance remains controversial [24]. In the liver, ADIPOR1 inhibits glucose production and increases insulin sensitivity by activating the AMPK pathway, whereas ADIPOR2 increases glucose uptake by the activation of the PPAR-α pathway [24]. Moreover, various aspects of adiponectin receptor signalling remain unclear, such as the connexion Author's personal copy OBES SURG (2011) 21:492–500 with cellular oxidative stress pathways. Regarding the mechanisms responsible for regulating adiponectin receptor expression, very little has been published. Hepatic, adipose and muscular adiponectin receptor levels are regulated in response to changes in nutritional conditions [38–41], probably to modify glucose metabolism and insulin sensibility. Nevertheless, there are contradictory data between different rodent models [39–41]. Currently, the role of adiponectin receptors under physiological and pathological variations remains unknown. Two recent articles studied the promoter activity of adiponectin receptors in cellular models. ADIPOR1 promoter is activated by FOXO1 [29], connecting with inflammatory pathways, whereas ADIPOR2 promoter is repressed by ATF3 [22], showing a connexion with endoplasmic oxidative stress pathways. In this paper, we report increases in adiponectin receptor expression levels during NAFLD progression. Furthermore, we report an increase in the gene expression for iNOS expression and antioxidant enzymes. Interestingly, we found a good correlation between the hepatic expressions of both adiponectin receptors and GPx1. Although our results may not be generalisable to overweight or obese subjects that would not meet the criteria for gastric bypass surgery, we believe our work useful for future studies of the molecular mechanism underlying the expression of adiponectin receptors and for future research to elucidate the role of adiponectin signalling during NAFLD progression. Acknowledgments This work was supported in part by a grant from Ciberehd (Ciberehd is funded by the Instituto de Salud Carlos III) and by a grant from Junta de Andalucía (CTS-4357). Conflicts of Interest None References 1. Fabbrini E, Sullivan S, Klein S. Obesity and nonalcoholic fatty liver disease: biochemical, metabolic, and clinical implications. Hepatology. 2010;51:679–89. 2. Marceau P, Biron S, Hould FS, et al. Liver pathology and metabolic syndrome X in severe obesity. 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