Psychiatric disorders have been widely reported to be associated with systemic inflammation upregulation and adiposity. However, there are no data that link adipose tissue inflammation to these mental disorders. The analysis of adipokines and inflammation-related markers in adipose tissue could help to elucidate the potential association between obesity and mental health. An observational study was conducted in samples of patients consisting of non-obese and obese subjects, who were diagnosed with anxiety or mood disorders. Gene expression of adiponectin (ADIPOQ), leptin (LEP) and inflammatory markers (IL6, IL1B, TNF, CCL2, CSF3, ITGAM, and PLAUR) were determined in visceral (VAT) and subcutaneous (SAT) adipose tissues. Our results showed that the gene expression of adipokines and inflammation-related markers was higher in the VAT and SAT of obese subjects compared with non-obese subjects. Regarding mental disorders, all the inflammatory genes in the VAT were significantly higher in non-obese subjects with anxiety or mood disorders than in subjects without mental disorders, except for TNF and ITGAM. Additionally, IL6 expression was significantly lower in SAT. In contrast, obese patients diagnosed with anxiety or mood disorders only showed significantly lower expression levels of IL1B in VAT and ADIPOQ in SAT when compared with obese subjects without mental disorders. These data suggest the potential involvement of VAT inflammation in anxiety and mood disorders, involving complex mechanisms which are strongly affected by obesity.
Currently, obesity represents a major priority for the public health agenda and its prevalence is alarming1. Obesity is a major risk factor for metabolic syndrome and type 2 diabetes, which comprise disease conditions such as cardiovascular, musculoskeletal, and psychiatric disorders2,3,4,5. In this sense, the presence of psychiatric disorders is common in those suffering from obesity. Therefore, the high rate of comorbidity includes not only medical, but also mental conditions, and efforts need to be taken to control its increase. Mental disorders, in concordance with the current state of obesity and metabolic syndrome, are expected to reach epidemic proportions worldwide between 2016 and 2050. Among them, depressive disorders are a significant contributor to the global burden of these disorders and affects 350 million people worldwide6. There have been several prospective epidemiological reports evaluating the relationship between body mass index (BMI) and psychiatric disorders. In fact, it has been suggested that obesity and associated factors could play a role in the development of psychiatric disorders7. Thus, it has been found that obesity increases the risk of developing depression, and conversely, depressive disorders were found to be predictive of developing obesity4,7,8. Other studies have shown that obesity is positively associated with anxiety9, and that psychosocial stress influences the development of adiposity10,11.
Evidence has suggested that inflammation may provide a mechanistic link between adiposity and mental disorders, and a low-grade inflammatory state is observed in obese subjects but also in depression, psychosis and other major psychiatric disorders. In adipose tissue, local inflammation is produced as a consequence of adipocyte hypertrophy, leading to an increased secretion of cytokines and chemokines together with an altered pattern of secreted adipokines11,12,13,14,15. An incompetent and dysfunctional adipose tissue is being described to be as a critical risk factor for the onset of obesity-associated metabolic complications12,13. Accordingly, increased proinflammatory cytokine levels have been also found in patients with neurodegeneration and mood disorder symptoms such as anhedonia, depressed mood, and lethargy4,14.
Although adipose tissue serves as an energy depot, visceral (VAT) and subcutaneous adipose tissues (SAT) are different in the sense that physiological and morphological aspects might be crucial in the metabolic homeostasis15. In fact, excessive VAT and SAT are key contributors to abdominal obesity but differ in their location, structural composition, metabolic activity and functional significance16. While VAT is strongly associated with insulin resistance, atherosclerosis and dyslipidemia in obese subjects, SAT demonstrates no association with these adverse obesity phenotypes. Furthermore, it has been also proposed that in deleterious conditions, VAT produces more pro-inflammatory molecules than SAT15,17. In addition to inflammatory mediators such as cytokines, adiponectin and leptin are two adipokines that are mainly secreted by adipose tissue and are known to play a pivotal role in the pathophysiology of obesity and associated metabolic disorders18. They have also been described to participate in the pathophysiology of psychiatric disorders such as major depression and anxiety-like disorders19,20.
In spite of all these investigative efforts, the inflammatory mechanisms underlying the link between obesity and mental disorders have not yet been characterized in the adipose tissue. Most studies have been limited to the analysis of proinflammatory mediators (i.e., cytokines) and adipokines in the plasma/serum of obese subjects or patients with mental disorders. In order to establish an association between the expression of inflammatory markers within adipose tissue and the presence of mental disorders in obesity, we examined the gene expression of relevant inflammatory markers and adipokines within adipose tissue in obese and non-obese subjects according to the diagnosis of anxiety and mood disorders. Through the present observational study, we have performed a description and analysis of variables and confounders, and differences in the gene expression of inflammatory markers and adipokines in the VAT and SAT were found in obese and non-obese subjects with mental disorders. However, further research is needed to establish the causality between alterations in inflammatory-associated markers in the adipose tissue and the presence of psychiatric disorders.
Clinical and biochemical characteristics in patients according to obesity
We explored the clinical and biochemical characteristics based on the obesity status. Whereas the non-obese group had a mean BMI of 25.0 ± 2.5 kg/m2, the obese group had a mean BMI of 46.6 ± 12.1 kg/m2. As shown in Table 1, no differences in mean age (56–57 years-old) or sex (36–45% women) were observed between both groups. Regarding biochemical parameters, we observed significant differences in several variables related to energy metabolism and inflammation in the blood. Thus, HOMA-IR and glucose levels were higher in the obese group (P < 0.001 and P < 0.05, respectively) compared with the non-obese group, but HDL levels were lower (P < 0.001).
Serum IL-6 and TNFα levels were significantly higher in the obese group (P < 0.05) than in the non-obese group. Consistently, correlation analyses showed a significant and positive association of BMI with IL-1β (r = 0.356, P = 0.036), IL-6 (r = 0.473, P = 0.004) and TNFα (r = 0.375, P = 0.032) levels.
Gene expression of adipokines and inflammatory markers in the adipose tissue of patients according to obesity
As a first approximation, a multiple correlation analysis between mRNA levels of these genes and BMI values was performed in the total sample. Overall, we observed positive and significant correlations between both adipose tissues, particularly in the VAT of obese participants (Table S1).
After confirming the association with BMI, the effects of obesity on mRNA levels of these genes were evaluated in the VAT and SAT using analysis of covariance(ANCOVA) with ‘obesity status’ (non-obese and obese groups) and ‘sex’ as factors and controlling for ‘age’. Data were examined for normality and all of the mRNA levels were log-transformed for analysis. Back-transformed marginal means on the original scale are shown in Table 2.
Visceral adipose tissue
We found a significant main association of ‘obesity status’ with mRNA levels of adiponectin (F1,102 = 6.890, P = 0.010), leptin (F1,102 = 6.062, P = 0.015), IL-1β (F1,102 = 14.327, P < 0.001), IL-6 (F1,102 = 7.191, P = 0.009), TNFα (F1,102 = 4.271, P = 0.041), PLAUR (F1,102 = 8.848, P = 0.004), CCL2 (F1,102 = 10.667, P = 0.001) and CSF3 (F1,102 = 16.403, P < 0.001). In fact, there were higher mRNA levels in the obese group relative to the non-obese group, except for adiponectin. However, we observed no association of ‘sex’ or interaction of ‘obesity status’ and ‘sex’ with mRNA levels of these adipokines and inflammatory markers in the VAT.
Subcutaneous adipose tissue
Multivariate ANCOVA revealed a significant main association of ‘obesity status’ with mRNA levels of leptin (F1,102 = 8.089, P = 0.005), IL-1β (F1,102 = 5.217, P = 0.024), TNFα (F1,102 = 7.150, P = 0.009), CCL2 (F1,102 = 6.227, P = 0.014), CSF3 (F1,102 = 8.593, P = 0.004), ITGAM (F1,102 = 14.416, P < 0.001) and PLAUR (F1,102 = 10.832, P = 0.001). Specifically, mRNA levels of leptin and inflammatory markers in the SAT were higher in the obese group than in the non-obese group. Similarly to VAT, we found no association of ‘sex’ or interaction between factors with mRNA levels of these mediators.
Correlation between visceral and subcutaneous adipose tissues
We conducted a secondary analysis to investigate the correlation between mRNA levels in VAT and SAT (Table S2). There was a positive and significant association between leptin mRNA levels and all of the inflammatory markers in the total sample. However, differences in these associations between VAT and SAT were detected in the non-obese and obese groups. While non-obese patients showed a significant correlation for leptin (P < 0.001), IL-1β (P < 0.001), IL-6 (P < 0.001) and TNFα (P < 0.05), obese patients showed a significant correlation for IL-6 (P < 0.01), ITGAM (P = 0.001) and PLAUR (P < 0.01).
Anxiety and mood disorders in patients according to obesity
Nearly 60% of patients were diagnosed with anxiety (n = 43) [age 59.1 (SD = 13.3) years-old] or mood (n = 22) [age 56.1 (SD = 13.6) years-old] disorders using the structured ‘International Mini Neuropsychiatric Interview’ (MINI). There were differences in the mean BMI of obese patients according to the presence of these mental disorders. Obese patients with anxiety or mood disorders had lower BMI than those patients without mental disorders [41.81 (95% CI = 37.61–46.01) kg/m2 and 55.30 (95% CI = 52.38–58.22) kg/m2, respectively]. In contrast, the non-obese group had similar mean BMI [25.11 (95% CI = 24.13–26.09) kg/m2 and 25.27 (95% CI = 24.31–26.23) kg/m2, respectively].
Gene expression of adipokines and inflammatory markers in the adipose tissue of non-obese and obese patients according to anxiety and mood disorders
Because mRNA levels of adipokines and inflammatory mediators were strongly associated with ‘obesity status’, we evaluated their association with anxiety and mood disorders separately for non-obese and obese patients. Two-way ANCOVA was used with ‘mental disorder status’ [non-mental disorders (non-MD) and anxiety/mood disorders (A/MD) groups] and ‘sex’ as factors and controlling for ‘BMI’, ‘age’ and ‘psychiatric medication’. Subsequently, mRNA levels of those genes which were significantly associated with ‘mental disorder status’ were again evaluated to distinguish between anxiety and mood disorders using ‘type of mental disorder’ as a factor [non-MD, anxiety disorders (ANX) and mood disorders (MOOD) subgroups].
All of the mRNA levels were log-transformed for analysis and estimated marginal means were presented in Figs 1 and 2 after back-transformation.
The composition of the non-obese group by sex was 9 female and 16 male patients with non-mental disorders, and 22 female and 9 male patients diagnosed with anxiety/mood disorders. Overall, we observed a significant main association of anxiety and mood disorders with mRNA levels of inflammatory mediators in the adipose tissue of non-obese patients, particularly in the VAT (Fig. 1). However, we found no differences in mRNA levels of adipokines.
As shown in Fig. 1A, ANCOVA revealed a significant association of ‘mental disorder status’ with mRNA levels of IL-1β (F1,47 = 10.885, P = 0.002), IL-6 (F1,47 = 12.004, P = 0.001), CCL2 (F1,47 = 7.802, P = 0.008), CSF3 (F1,47 = 4.518, P = 0.039) and PLAUR (F1,47 = 13.423, P = 0.001) in the VAT, and mRNA levels of IL-6 (F1,47 = 6.046, P = 0.018) in the SAT. In all these cases, non-obese patients with anxiety/mood disorders (A/MD subgroup) showed significantly higher mRNA levels of these genes relative to non-obese patients without mental disorders (non-MD subgroup). In contrast, there were no associations of ‘sex’ or interaction between factors with mRNA levels of these mediators.
With respect to the distinction between anxiety and mood disorders (Fig. 1B), we found a main association of ‘type of mental disorder’ with mRNA levels of IL-1β (F2,45 = 5.212, P = 0.009), IL-6 (F2,45 = 5.458, P = 0.008), CCL2 (F2,45 = 4.076, P = 0.024) and PLAUR (F1,47 = 7.996, P = 0.001) in the VAT. Post hoc comparisons revealed that non-obese patients diagnosed with anxiety or mood disorders (A/MD subgroup) had significantly higher mRNA levels of IL-1β (P < 0.01), IL-6 (P < 0.01) and PLAUR (P < 0.001 and P < 0.05, respectively) than non-obese patients without mental disorders (non-MD). For CCL2, we observed that only patients with anxiety disorders (ANX subgroup) had significantly (P < 0.05) higher mRNA levels.
The composition of the obese group by sex was 11 female and 8 male patients with non-mental disorders, and 23 female and 11 male patients diagnosed with anxiety/mood disorders. In the obese group, there were significant associations of anxiety and mood disorders with mRNA levels of inflammatory mediators displaying a lower expression, except for IL-1β in the VAT (Fig. 2).
As shown in Fig. 2A, ANCOVA revealed a main association of ‘mental disorder status’ with mRNA levels of IL-1β (F1,46 = 8.726, P = 0.005) and adiponectin (F1,46 = 11.663, P = 0.001) in VAT and SAT, respectively. Thus, IL-1β and adiponectin mRNA levels were significantly lower in obese patients with anxiety/mood disorders (A/MD subgroup) than in obese patients without mental disorders (non-MD subgroup). Similarly to the non-obese group, there were no significant associations of ‘sex’ or interaction between factors with mRNA levels of these genes.
When we separated anxiety and mood disorders (Fig. 2B), ANCOVA showed a main association of ‘type of mental disorder’ with mRNA levels of IL-1β (F2,44 = 3.722, P = 0.032) and adiponectin (F2,44 = 5.834, P = 0.006). Pairwise comparisons indicated that obese patients diagnosed with anxiety disorders (ANX subgroup) had significantly lower adiponectin mRNA levels (P < 0.05) than in non-obese patients without mental disorders (non-MD subgroup), whereas obese patients with mood disorders (MOOD subgroup) had lower mRNA levels of IL-1β (P < 0.05) and adiponectin (P < 0.01).
Because we found lower IL-1β mRNA levels in obese patients with anxiety/mood disorders (A/MD subgroup) than in patients without mental disorders (non-MD subgroup), we measured the protein expression of IL-1β in the blood. Unlike what we found in the VAT, we observed higher serum IL-1β levels in obese patients with anxiety or mood disorders than in the non-MD subgroup (0.046 ± 0.080 and 0.132 ± 0.055 pg/mL, respectively) after controlling for BMI. In addition to IL-1β, IL-6 and TNFα serum levels were higher in this obese subgroup (IL-6: 3.54 ± 4.10 vs. 2.90 ± 1.41 pg/mL; and TNFα: 2.96 ± 1.27 vs. 2.38 ± 1.48 pg/mL; respectively).
There is increasing evidence that obesity, anxiety and depression are comorbid disorders21,22. Because adipose tissue dysfunction could be involved in the development of psychiatric disorders, previous studies have examined the relationship between adiposity and mental health using markers of inflammation in the blood4,19,23. Accordingly, we showed that obese subjects have higher serum cytokine levels compared with non-obese subjects, particularly in obese patients with anxiety or mood disorders. However, the aim of the present study was to describe and analyze the potential association between the gene expression of inflammatory markers (and adipokines) in adipose tissue and the presence of prevalent psychiatric disorders (i.e., anxiety and mood disorders) in obese and non-obese patients.
The main findings of this observational study were as follows: (1) The gene expression of inflammation-related markers and adipokines was higher in the VAT and SAT of obese patients with respect to non-obese patients, which was in line with the strong and positive correlation between mRNA levels of these mediators and BMI in both adipose tissues; (2) The gene expression of relevant inflammation-related markers (IL1B, IL6, CCL2, CSF3 and PLAUR) were significantly higher in the VAT of non-obese subjects with anxiety or mood disorders, whereas only IL6 expression was higher in the SAT among non-obese patients without mental disorders; (3) In contrast, obese patients diagnosed with anxiety or mood disorders only showed significantly lower IL1B levels in the VAT and ADIPOQ in the SAT relative to obese subjects without mental disorders.
Therefore, while the obesity status was associated with higher expression of inflammatory markers in both adipose tissues, mood and anxiety disorders were associated with higher gene expression of inflammatory markers in the VAT of non-obese patients but not in obese patients. These results in non-obese patients, suggest that VAT could be more sensitive than SAT to changes in the inflammatory response linked to mental disorders. According to our results, studies in women have shown that VAT is related to mood disorders, and depressive symptoms are indeed associated with increased inflammation in this type of adipose tissue24. Moreover, emerging evidence indicates that VAT may impair resilience to stress, and therefore differentially impact the subsequent risk of mood and/or anxiety disorders25.
Mental disorders such as depressive disorders and anxiety have been suggested to be related to systemic inflammation upregulation4,26. In fact, patients with major depression have increased levels of inflammatory markers and cytokines in the blood14. Increasing evidence indicates that one possible important source of inflammation in mood disorders could be adiposity27 assuming that adipose tissue is a known source of inflammatory factors including adipokines, chemokines, and cytokines28. On the other hand, it is well known that macrophages infiltrate into white adipose tissue29,30 and this contributes to the production of inflammatory factors such as chemokines and the development of some morbidities such as obesity and metabolic alterations. Interestingly, our data suggest that inflammation modulated by IL-1β, IL-6, PLAUR, and CCL2 in the VAT could be related to anxiety and mood disorders as long as patients are not in an obesity state. Several studies are in agreement and have shown that these proinflammatory factors are higher in serum from subjects with psychiatric disorders and are involved in the progression and severity of depressive and anxiety disorders26,31. Cytokines such as IL-1β and IL-6 have been found to have neuroendocrine activity and induce behavioral changes related to anxiety32, including preclinical models33. Thus, IL-1β contributes to psychological stress responses and has been implicated in several psychiatric disorders, most notably in major depressive disorders, including a specific behavioral complex, sickness behavior, which is characterized by sleep disorders, anxiety, and diminished social interactions34. Also, a preclinical study has shown that IL-1β modulates anxiety and fear-related behaviors35. Regarding IL-6, this cytokine has been reported to be higher in depressed subjects than in non-depressed subjects31,36, which is in line with our results since IL-6 mRNA levels were altered in subjects with both anxiety and mood disorders. In addition to cytokines, both CCL2 and PLAUR mRNA levels were found to be higher in non-obese patients with mental disorders. Other studies have also shown that CCL2 levels were significantly higher in patients with major depression and in female patients with stress-related mental disorders37,38.
Regarding obese patients, the relationship between inflammatory markers and mental disorders was no observed, with the exception of IL-1β. From our point of view, this lack of differences in the gene expression of inflammatory markers in the adipose tissue could be the consequence of an exacerbated obesity-induced inflammation and, therefore this excessive inflammatory response could prevent from detecting the effects of these mental disorders. However, this overlapping effect of obesity is mere speculation because the causality between alterations of inflammatory mediators and obesity or mental disorders cannot be established in an observational study such as this one. The only significant differences observed in the obese group with respect to inflammatory factors were in IL-1β mRNA levels. Thus, the IL1B expression in the VAT was lower in obese patients with mood disorders than in those patients without mental disorders. This surprising finding was confirmed after including BMI as a cofactor for the statistical analysis of IL-1β mRNA levels in obese patients according to the presence of mental disorders. Moreover, lower IL-1β mRNA levels were also observed in obese patients with mood and/or anxiety disorders after selecting subjects with comparable BMI values (data not shown).
Our results show that the gene expression of adiponectin was the only adipokine that was affected by anxiety or mood disorders resulting in lower mRNA levels in the SAT of obese patients with anxiety and mood disorders. These findings are concordant with the fact that adiponectin activity has been well-described to be strongly associated with several mental disorders39. Thus, decreased serum adiponectin levels have been also reported in major depressive disorders, panic disorders, and schizophrenia23,40,41. Furthermore, it has been described that adiponectinemia reduction is related to major depression severity42. Other studies have suggested that adiponectin levels are critical for the determination of susceptibility to depressive behaviors and that adiponectin could be a potential therapeutic target for the treatment of depression43.
These data indicate that it is relevant to study how adipose tissue inflammation could be associated with the presence of anxiety and mood disorders in both obese and non-obese subjects since there is evidence of a bidirectional link between obesity or metabolic alterations and neuropsychiatric status. In this regard, various studies converge to show that inflammatory processes originating from the adipose tissue environment spread to the brain where they lead to substantial changes in neuroendocrine circuitry activity, neurotransmitter metabolism, and signaling, and also in neurogenesis. Together, these alterations contribute to shape the propitious bases for the development of obesity-related neuropsychiatric comorbidities4. In addition, there is neuroanatomical and functional evidence for the sympathetic nervous system innervation of white adipose tissue, which has at least three functions: lipolysis, regulation of fat cell number and control of some white adipose tissue-secreted proteins44,45. Consequently, the present results and previously published data, point to the necessity of great efforts to elucidate the mechanisms behind the cross-talk between brain and adipose tissue and subsequently between obesity and mental disorders.
Despite the efforts in the design phase and selection of patients, and the use of appropriate statistical analyses, we are aware of the limitations of this observational study. (1) A main disadvantage is that the causality between alterations in the gene expression of inflammatory mediators/adipokines in adipose tissue and obesity or mental disorders cannot be established. (2) The validity of the present results with a relatively small sample size has to be proven in a larger cohort of patients. (3) A longitudinal study is needed to evaluate the gene expression of inflammatory factors and adipokines in both adipose tissues according to the variation in the BMI of the same patients with or without these mental disorders. Complementarily, preclinical studies will be able to elucidate the mechanisms underlying the reciprocal relationship between obesity and psychiatric disorders. (4) There are numerous socio-demographic and physiological variables that could influence the expression of these genes in adipose tissue, and the inclusion of potential confounding variables and covariates in the present statistical analyses has important restrictions related to the sample size to avoid overfitting. For example, although the use of psychotropic medications was controlled, there is great diversity in the use of other drugs such as statins (particularly in obese patients) that should be kept in mind. (5) Finally, we cannot discard the effects of other common psychiatric disorders (e.g., psychotic and personality disorders) that were not considered in the MINI interview.
Materials and Methods
Patients and recruitment
The present observational study was conducted in 109 patients waiting for bariatric or abdominal laparoscopic surgery at the Hospital Regional Universitario de Málaga and Hospital Universitario Virgen de la Victoria (Málaga, Spain), who were psychiatrically assessed.
The procedure for recruiting was non-random convenience sampling according to the participation criteria and medical records. Therefore, the initial cohort consisted of 120 subjects grouped according to their obesity and psychiatric status into non-obese subjects with anxiety/mood disorders, non-obese subjects with no mental disorders, obese subjects with anxiety/mood disorders and obese subject with no mental disorders (n = 30 per group). The grouping of participants was subsequently checked using a structured psychiatric assessment 2 weeks prior to surgery.
All participants were recruited voluntarily based on participation criteria for the study:
Inclusion criteria included the following: Subjects 18 or over on the bariatric or abdominal laparoscopic surgery waiting list, willing to offer adipose tissue samples and giving written informed consent.
Exclusion criteria for the recruitment of participants were diagnosis of type 2 diabetes treated with insulin, acute or chronic inflammatory diseases, infectious diseases or cardiovascular diseases in the 6 months prior to participation in the study on account of the potential effect of these diseases or pharmacological treatments on inflammatory signals. Subjects diagnosed with both anxiety and mood disorders together or diagnosed with other mental disorders distinct to anxiety and mood disorders were also excluded.
Finally, the definitive sample consisted of non-obese subjects with anxiety/mood disorders (n = 31), non-obese subjects with no mental disorders (n = 25), obese subjects with anxiety/mood disorders (n = 34) and obese subjects with no mental disorders (n = 19). Psychiatric characteristics according to obesity are shown in Table S3.
Written informed consent was obtained from each participant. The present study and protocols were approved by the Ethics Committee of the Hospital Regional Universitario de Málaga and Hospital Universitario Virgen de la Victoria (PI10/01947) in accordance with the ‘Ethical Principles for Medical Research Involving Human Subjects’ adopted in the Declaration of Helsinki by the World Medical Association (64th WMA General Assembly, Fortaleza, Brazil, October 2013), Recommendation No. R (97) 5 of the Committee of Ministers to Member States on the Protection of Medical Data (1997), and the Spanish Data Protection Act (Ley Orgánica 15/1999 de Protección de Datos, LOPD).
Venous blood was extracted into 10 mL K2-EDTA tubes (BD, Franklin Lakes, NJ, USA) and immediately processed to obtain serum, prior to the start of the surgical procedure and anesthesia induction. During the surgery, approximately 500 mg biopsies of subcutaneous (SAT) and visceral adipose (VAT) tissue were obtained from the same anatomical area at the beginning of the surgical procedure: SAT samples from the abdominal wall and VAT samples from the greater omentum. All of the samples were stored immediately at 80 °C.
Psychiatric evaluations were conducted 2 weeks prior to surgery and consisted of a structured psychiatric interview using the Spanish version of ‘International Mini Neuropsychiatric Interview’, version 5.0.0 (MINI), which was administered by clinical psychologists, specialized in clinical diagnostic interviews46. The MINI is a brief high structured interview that is compatible with the diagnostic criteria established by the ‘Diagnostic and Statistical Manual of Mental Disorders IV edition, text revision’ (DSM-IV-TR) and the ‘International Classification of Diseases’ (ICD-10). The MINI is structured in modules that explore common disorders of Axis I of the DSM-IV, as well as the risk of suicide and anti-social personality disorder46. The MINI interview has an approximate duration of 20 min and has been proven to have satisfactory reliability. In the present study, we selected patients with no mental disorders according to the MINI [i.e., negative for 16 (A to P) modules assessing the major Axis I psychiatric disorders in DSM-IV and ICD-10], patients with anxiety disorders (modules: E. panic disorder, F. agoraphobia, G. social phobia, H. obsessive-compulsive disorder, I. posttraumatic stress disorder and O. generalized anxiety disorder) and mood disorders or episodes (modules: A. major depressive episode, B. dysthymia, C. suicidality, D. manic or hypomanic episode)47,48.
The prevalence of psychotropic medication use during the last year was also determined.
Biochemical determinations in serum samples
The participants’ serum samples were assessed for biochemical parameters in duplicate [glucose, total cholesterol, high-density lipoprotein (HDL), low-density lipoprotein (LDL), and triglycerides] and were measured by standard enzymatic methods. Insulin was analyzed by an immunoradiometric assay (BioSource International, Camarillo, CA, USA). HOMA-IR was calculated from fasting insulin and glucose with the following equation: HOMA-IR = fasting insulin (µIU/mL) x fasting glucose (mol/L)/22.549. IL-1β, IL-6 and TNFα concentrations (pg/mL) were measured in serum with commercial enzyme-linked immunosorbent assay (ELISA) kits following the manufacturer’s instructions (Abcam plc, Cambridge, UK).
Extraction of mRNA from adipose tissue biopsies and real-time PCR
Gene expression was assessed by real time-quantitative (RT-q) PCR after mRNA extraction. Total RNA was isolated from adipose tissue samples using the Trizol RNA isolation method (Invitrogen, Carlsbad, CA, USA) and purified with the RNeasy Lipid kit (QIAGEN, Valencia, CA, USA). RNA was reverse transcribed using Transcriptor Reverse Transcriptase kit (Roche Diagnostic, Barcelona, Spain). The amplifications were performed using a MicroAmp® Optical 96-well reaction plate (Applied Biosystems, Barcelona, Spain) on an ABI 7500 Fast Real-Time PCR System (Applied Biosystems, Barcelona, Spain). RT qPCR reactions were carried out for the following genes using specific TaqMan® Gene Expression Assays: ADIPOQ, LEP, IL6, IL1B, TNF, CCL2, CSF3, ITGAM, and PLAUR. During PCR, the Ct values for each amplified product were determined using a threshold value of 0.1. The specific signals were normalized by constitutively expressed cyclophilin (PPIA) signals using the formula 2−ΔCt.
All data in the tables are expressed as number and percentage of subjects [n (%)], mean and standard deviation (mean ± SD) or mean and 95% confidence interval [mean (95% CI)]. The significance of differences in categorical variables was determined by using Fisher’s exact test or Chi-square test; while continuous variables were evaluated using Student’s t-test or the Mann-Whitney U test.
Relative mRNA levels of genes in the VAT and SAT were analyzed using multivariate and univariate analysis of covariance (ANCOVA) as a general linear model to indicate the relative effect of independent variables (factors) [i.e., obesity status (non-obese and obese groups), sex (women and men), mental disorder status [non-mental disorders (non-MD) and anxiety/mood disorders (A/MD) subgroups], type of mental disorder [non-MD, anxiety disorders (ANX) and mood disorders (MOOD) subgroups] and their interactions on mRNA expression, and controlling for covariates (i.e., age, BMI and psychiatric medication)50. Because this is an observational research design, we used the term ‘association’ to describe effects of independent variables (or interaction) with dependent variables in the ANCOVA models. Post hoc tests (Sidak correction) were used to compare subgroups. To ensure statistical assumptions for positively skewed distributions, we used log(10)-transformation of mRNA levels for all genes. Estimated marginal means and (95% CI) of mRNA levels were presented in the figures after back-transformation.
Correlation analyses were performed using the Pearson’s correlation coefficient (r) and Benjamini and Hochberg procedure was employed for correction of multiple comparisons.
Thresholds of 0.05 were applied for P-values. Statistical analyses were performed using Graph-Pad Prism version 5.04 (GraphPad Software, San Diego, CA, USA) and IBM SPSS Statistical version 22 (IBM, Armonk, NY, USA) softwares.
(WHO), W. H. O. Obesity and overweight. Fact Sheet (2017).
Despres, J. P. & Lemieux, I. Abdominal obesity and metabolic syndrome. Nature 444, 881–887 (2006).
Greenfield, J. R. & Campbell, L. V. Insulin resistance and obesity. Clin Dermatol 22, 289–295 (2004).
Castanon, N., Lasselin, J. & Capuron, L. Neuropsychiatric comorbidity in obesity: role of inflammatory processes. Front Endocrinol (Lausanne) 5, 74 (2014).
Atlantis, E. & Baker, M. Obesity effects on depression: systematic review of epidemiological studies. Int J Obes (Lond) 32, 881–891 (2008).
Guilbert, J. J. The world health report 2002 - reducing risks, promoting healthy life. Educ Health (Abingdon) 16, 230 (2003).
Simon, G. E. et al. Association between obesity and psychiatric disorders in the US adult population. Arch Gen Psychiatry 63, 824–830 (2006).
Luppino, F. S. et al. Overweight, obesity, and depression: a systematic review and meta-analysis of longitudinal studies. Arch Gen Psychiatry 67, 220–229 (2010).
Gariepy, G., Nitka, D. & Schmitz, N. The association between obesity and anxiety disorders in the population: a systematic review and meta-analysis. Int J Obes (Lond) 34, 407–419 (2010).
Wardle, J., Chida, Y., Gibson, E. L., Whitaker, K. L. & Steptoe, A. Stress and adiposity: a meta-analysis of longitudinal studies. Obesity (Silver Spring) 19, 771–778 (2011).
Capuron, L. & Miller, A. H. Immune system to brain signaling: neuropsychopharmacological implications. Pharmacol Ther 130, 226–238 (2011).
Petersen, K. F. & Shulman, G. I. Etiology of insulin resistance. Am J Med 119, S10–16 (2006).
Tan, C. Y. & Vidal-Puig, A. Adipose tissue expandability: the metabolic problems of obesity may arise from the inability to become more obese. Biochem Soc Trans 36, 9 (2008).
Miller, A. H., Maletic, V. & Raison, C. L. Inflammation and its discontents: the role of cytokines in the pathophysiology of major depression. Biol Psychiatry 65, 732–741 (2009).
Bays, H. E. et al. Pathogenic potential of adipose tissue and metabolic consequences of adipocyte hypertrophy and increased visceral adiposity. Expert Rev Cardiovasc Ther 6, 343–368 (2008).
Neeland, I. J. et al. Associations of visceral and abdominal subcutaneous adipose tissue with markers of cardiac and metabolic risk in obese adults. Obesity (Silver Spring) 21, E439–447 (2013).
Trayhurn, P. & Beattie, J. H. Physiological role of adipose tissue: white adipose tissue as an endocrine and secretory organ. Proc Nutr Soc 60, 329–339 (2001).
Balistreri, C. R., Caruso, C. & Candore, G. The role of adipose tissue and adipokines in obesity-related inflammatory diseases. Mediators Inflamm 2010, 802078 (2010).
Diniz, B. S. et al. Reduced serum levels of adiponectin in elderly patients with major depression. J Psychiatr Res 46, 1081–1085 (2012).
Liu, J. et al. Acute administration of leptin produces anxiolytic-like effects: a comparison with fluoxetine. Psychopharmacology (Berl) 207, 535–545 (2010).
Lin, H. Y. et al. Psychiatric disorders of patients seeking obesity treatment. BMC Psychiatry 13, 1 (2013).
Daly, M. The relationship of C-reactive protein to obesity-related depressive symptoms: a longitudinal study. Obesity (Silver Spring) 21, 248–250 (2013).
Lehto, S. M. et al. Serum adiponectin and resistin levels in major depressive disorder. Acta Psychiatr Scand 121, 209–215 (2010).
Everson-Rose, S. A. et al. Depressive symptoms and increased visceral fat in middle-aged women. Psychosom Med 71, 410–416 (2009).
Peters, A. & McEwen, B. S. Stress habituation, body shape and cardiovascular mortality. Neurosci Biobehav Rev 56, 139–150 (2015).
Duivis, H. E., Vogelzangs, N., Kupper, N., de Jonge, P. & Penninx, B. W. Differential association of somatic and cognitive symptoms of depression and anxiety with inflammation: findings from the Netherlands Study of Depression and Anxiety (NESDA). Psychoneuroendocrinology 38, 1573–1585 (2013).
Shelton, R. C. & Miller, A. H. Inflammation in depression: is adiposity a cause? Dialogues Clin Neurosci 13, 41–53 (2011).
Lumeng, C. N., Deyoung, S. M., Bodzin, J. L. & Saltiel, A. R. Increased inflammatory properties of adipose tissue macrophages recruited during diet-induced obesity. Diabetes 56, 16–23 (2007).
Weisberg, S. P. et al. Obesity is associated with macrophage accumulation in adipose tissue. J Clin Invest 112, 1796–1808 (2003).
Xu, H. et al. Chronic inflammation in fat plays a crucial role in the development of obesity-related insulin resistance. J Clin Invest 112, 1821–1830 (2003).
Young, J. J., Bruno, D. & Pomara, N. A review of the relationship between proinflammatory cytokines and major depressive disorder. J Affect Disord 169, 15–20 (2014).
O’Donovan, A. et al. Clinical anxiety, cortisol and interleukin-6: evidence for specificity in emotion-biology relationships. Brain Behav Immun 24, 1074–1077 (2010).
de Miranda, A. S. et al. Anxiety-like behavior and proinflammatory cytokine levels in the brain of C57BL/6 mice infected with Plasmodium berghei (strain ANKA). Neurosci Lett 491, 202–206 (2011).
Dantzer, R. Cytokine-induced sickness behavior: where do we stand? Brain Behav Immun 15, 7–24 (2001).
Koo, J. W. & Duman, R. S. Interleukin-1 receptor null mutant mice show decreased anxiety-like behavior and enhanced fear memory. Neurosci Lett 456, 39–43 (2009).
Dowlati, Y. et al. A meta-analysis of cytokines in major depression. Biol Psychiatry 67, 446–457 (2010).
Asberg, M. et al. Novel biochemical markers of psychosocial stress in women. PLoS One 4, e3590 (2009).
Sutcigil, L. et al. Pro- and anti-inflammatory cytokine balance in major depression: effect of sertraline therapy. Clin Dev Immunol 2007, 76396 (2007).
Wedrychowicz, A., Zajac, A., Pilecki, M., Koscielniak, B. & Tomasik, P. J. Peptides from adipose tissue in mental disorders. World J Psychiatry 4, 103–111 (2014).
Cohn, T. A. et al. Insulin resistance and adiponectin levels in drug-free patients with schizophrenia: A preliminary report. Can J Psychiatry 51, 382–386 (2006).
Unsal, C. et al. Low plasma adiponectin levels in panic disorder. J Affect Disord 139, 302–305 (2012).
Leo, R. et al. Decreased plasma adiponectin concentration in major depression. Neurosci Lett 407, 211–213 (2006).
Liu, J. et al. Adiponectin is critical in determining susceptibility to depressive behaviors and has antidepressant-like activity. Proc Natl Acad Sci USA 109, 12248–12253 (2012).
Bartness, T. J., Kay Song, C., Shi, H., Bowers, R. R. & Foster, M. T. Brain-adipose tissue cross talk. Proc Nutr Soc 64, 53–64 (2005).
Yi, C. X. & Tschop, M. H. Brain-gut-adipose-tissue communication pathways at a glance. Dis Model Mech 5, 583–587 (2012).
Sheehan, D. V. et al. The Mini-International Neuropsychiatric Interview (M.I.N.I.): the development and validation of a structured diagnostic psychiatric interview for DSM-IV and ICD-10. J Clin Psychiatry 59 (Suppl 20), 22–33; quiz 34–57 (1998).
Verhoeven, F. E. A. et al. Agreement between clinical and MINI diagnoses in outpatients with mood and anxiety disorders. J Affect Disord 221, 268–274 (2017).
Wiener, C. D. et al. Mood disorder, anxiety, and suicide risk among subjects with alcohol abuse and/or dependence: a population-based study. Rev Bras Psiquiatr, 0 (2017).
Garrido-Sanchez, L. et al. Munc18c in adipose tissue is downregulated in obesity and is associated with insulin. PLoS One 8, e63937 (2013).
Garcia-Marchena, N. et al. Plasma Chemokines in Patients with Alcohol Use Disorders: Association of CCL11 (Eotaxin-1) with Psychiatric Comorbidity. Front Psychiatry 7, 214 (2016).
The authors wish to thank all the subjects for their collaboration. The CIBER Fisiopatología de la Obesidad y Nutrición (CIBEROBN) is part of the ‘Instituto de Salud del Carlos III’ (ISCIII) Project. Authors thank D.W.E. Ramsden for help with the English language version of the text. This work was supported in part by grants from the Instituto de Salud Carlos III (ISCIII)/FEDER-UE (PI10/01947, PI13/02628). CTS-7895 and CTS-546 funded by the Regional Ministry of Innovation of the Andalusian Government, Andalusia, Spain; and co-funded by the Fondo Europeo de Desarrollo Regional–FEDER. RE and YDDO are under a contract of a ‘Nicolas Monarde’ (C-0030-2016, RC0006-2015) programme from the Servicio Andaluz de Salud, Regional Ministry of health of the Andalusian Government, Andalusia, Spain. FJP holds a ‘Miguel Servet I’ research contract from ISCIII and ERDF-UE (CP14/00212).
The authors declare no competing interests.
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Coín-Aragüez, L., Pavón, F.J., Contreras, A. et al. Inflammatory gene expression in adipose tissue according to diagnosis of anxiety and mood disorders in obese and non-obese subjects. Sci Rep 8, 17518 (2018). https://doi.org/10.1038/s41598-018-35759-9
- Mood Disorders (MOOD)
- Inflammation-related Markers
- Subcutaneous Adipose Tissue (SAT)
- Mental Disorders
- Mini International Neuropsychiatric Interview
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