Fluoxetine-induced hepatic lipid accumulation is linked to elevated serotonin production.

Fluoxetine, a commonly prescribed selective serotonin reuptake inhibitor antidepressant, has been shown to increase hepatic lipid accumulation, a key factor in the development of nonalcoholic fatty liver disease. Interestingly, fluoxetine has also been reported to increase peripheral serotonin synthesis. As emerging evidence suggests that serotonin may be involved in the development of nonalcoholic fatty liver disease, we sought to determine if fluoxetine-induced hepatic lipid accumulation is mediated via altered serotonin production. Fluoxetine treatment increased lipid accumulation in association with increased mRNA expression of tryptophan hydroxylase 1 (Tph1, serotonin biosynthetic enzyme) and intracellular serotonin content. Serotonin alone had a similar effect to increase lipid accumulation. Moreover, blocking serotonin synthesis reversed the fluoxetine-induced increases in lipid accumulation. Collectively, these data suggest that fluoxetine-induced lipid accumulation can be mediated, in part, by elevated serotonin production. These results suggest a potential therapeutic target to ameliorate the adverse metabolic effects of fluoxetine exposure.

Fructosa, un factor clave modificable en la patogenia del síndrome metabólico, la esteatosis hepática y la obesidad / Fructose, a modifiable key factor in the pathogenic basis of metabolic syndrome, NAFLD and obesity / Frutose, um fator chave modificável na patogênese da síndrome metabólica, esteatose hepática e obesidade

Resumen: En esta revisión se resume el rol específico que el exceso de consumo de fructosa más allá de sus calorías puede tener en el desarrollo del síndrome metabólico, la esteatosis hepática no alcohólica y su asociación con la obesidad. Se desglosan los efectos de la fructosa (en comparación con la glucosa) en la esteatosis hepática, lo que genera la insulino-resistencia y la hipertrigliceridemia. Por su metabolismo hepático mayoritario y la falta de regulación, los flujos altos de fructosa consumen ATP generando ácido úrico, producen metabolitos tóxicos, como ceramidas y metilglioxal, y activan la síntesis de lípidos. Además, se analizan los efectos en el tejido adiposo, la activación del cortisol y las hormonas involucradas en el control de la saciedad, todas las cuales se ven afectadas por el consumo de fructosa. La insulino-resistencia hepática inicial se complica con insulino-resistencia sistémica, que genera leptino-resistencia y un ciclo de hiperfagia. Estos resultados subrayan la necesidad de intervenciones clínicas y educativas dentro de la población para regular o reducir el consumo de fructosa, especialmente en niños y adolescentes, sus principales consumidores.

Summary: This review summarizes the specific role that excess fructose consumption (beyond its calories) may have in the development of MetS, NAFLD and its association with obesity. The effects of fructose (compared to glucose) on hepatic steatosis are discussed as well as their consequence: insulin resistance and hypertriglyceridemia. Unlike glucose, more than 80% ingested fructose stays in the liver, and due to lack of fine metabolic regulation, high fructose flows consume ATP generating uric acid, produce toxic metabolites such as ceramides and methylglyoxal and activate lipid synthesis. In addition, the study analyzes the effects of fructose on adipose tissue, cortisol activation and hormones involved in satiety control, all of which are affected by fructose consumption. The initial hepatic insulin resistance is complicated by systemic insulin resistance, which generates leptin resistance and a hyperphagia cycle. These results underscore the need for clinical and educational interventions within the population to regulate / reduce fructose consumption, especially in children and adolescents, their main consumers.

Resumo: No momento vivemos uma pandemia causada pelo vírus SARS-CoV-2, COVID-19, sendo o mais recomendado ficar em casa para reduzir o contágio e que este seja reduzido ao mínimo possível. No século 21, a tecnologia está mais presente do que nunca e faz parte do nosso dia a dia. Tendo em vista que há significativo abuso da mesma, principalmente por adolescentes, na nossa perspectiva que promove o movimento e a redução do comportamento sedentário, propomos o uso de videogames ativos em substituição aos videogames convencionais. Para isso, fizemos uma revisão dos principais benefícios que estas podem trazer, tanto para a população mais jovem como para os idosos. Esta última faixa etária é uma das mais afetadas pela pandemia e, portanto, há uma forte recomendação para que fiquem em casa. No entanto, é recomendável usá-lo com responsabilidade e não investir tempo excessivo que possa causar danos.

Combining metformin therapy with caloric restriction for the management of type 2 diabetes and nonalcoholic fatty liver disease in obese rats.

Weight loss is recommended for patients with nonalcoholic fatty liver disease (NAFLD), while metformin may lower liver enzymes in type 2 diabetics. Yet, the efficacy of the combination of weight loss and metformin in the treatment of NAFLD is unclear. We assessed the effects of metformin, caloric restriction, and their combination on NAFLD in diabetic Otsuka Long-Evans Tokushima Fatty (OLETF) rats. Male OLETF rats (age 20 weeks; n = 6-8 per group) were fed ad libitum (AL), given metformin (300 mg·kg(-1)·day(-1); Met), calorically restricted (70% of AL; CR), or calorically restricted and given metformin (CR+Met) for 12 weeks. Met lowered adiposity compared with AL but not to the same magnitude as CR or CR+Met (p < 0.05). Although only CR improved fasting insulin and glucose, the combination of CR+Met was needed to improve post-challenge glucose tolerance. All treatments lowered hepatic triglycerides, but further improvements were observed in the CR groups (p < 0.05, Met vs. CR or CR+Met) and a further reduction in serum alanine aminotransferases was observed in CR+Met rats. CR lowered markers of hepatic de novo lipogenesis (fatty acid synthase, acetyl-CoA carboxylase (ACC), and stearoyl-CoA desaturase-1 (SCD-1)) and increased hepatic mitochondrial activity (palmitate oxidation and ß-hydroxyacyl CoA dehydrogenase (ß-HAD) activity). Changes were enhanced in the CR+Met group for ACC, SCD-1, ß-HAD, and the mitophagy marker BNIP3. Met decreased total hepatic mTOR content and inhibited mTOR complex 1, which may have contributed to Met-induced reductions in de novo lipogenesis. These findings in the OLETF rat suggest that the combination of caloric restriction and metformin may provide a more optimal approach than either treatment alone in the management of type 2 diabetes and NAFLD.

DHEA and non-alcoholic fat liver disease: increased gene expression of peroxisome proliferation-activated receptor γ (PPARγ) and fatty acid synthase (FAS) / DHEA e doença gordurosa hepática não-alcoólica: aumento na expressão gênica do peroxisome proliferation-activated receptor γ (PPARγ) e ácido graxo sintase (FAS)

Dehydroespiandrosterone (DHEA) is associated with improvements in chronic degenerative diseases, including obesity, insulin resistance, and cardiovascular diseases. Nevertheless, it is observed an increase in its concentration in individuals with liver lipid infiltration, but it is not precise if this condition emerges as a cause or a consequence. In this way, we aimed to identify gene expression alterations in lipid and glucose liver metabolism markers, as well as oxidative stress markers. For this purpose, male Wistar rats, 12-14 months old were treated with subcutaneous injections of DHEA (only dose of 10 mg kg-1); and after 7 days, hepatic gene expression by PCR real time were performed for the following genes: G6Pase, PEPCK, FAS, PPARγ, malic enzyme, ChREBP, LXR, catalase, GPx, iNOS, NADPH oxidase subunits and PCNA. We observed a tendency of reduction in G6Pase gene expression in treated group (p = 0.08). In addition, it was identified an increase in liver PPARγ and FAS gene expressions, two markers of increased activity of lipogenic pathway. We also observed an increase in iNOS gene expression, a known inductor of systemic and hepatic insulin resistance. In conclusion, our data indicates that the treatment with DHEA can be associated with the development of liver lipid infiltration and hepatic insulin resistance.

A deidroepiandrosterona (DHEA) encontra-se associada a melhorias em quadros de obesidade, resistência à insulina e doenças cardiovasculares. Porém, observa-se um aumento na sua concentração em indivíduos portadores de infiltração lipídica hepática, mas sem saber precisar se o mesmo surge como causa ou consequência. Assim, objetivamos identificar alterações na expressão gênica hepática de marcadores relacionados ao metabolismo lipídico e glicídico e de estresse oxidativo. Para tanto, ratos machos com 12-14 meses de idade foram tratados com injeção subcutânea de DHEA (dose única 10 mg kg-1), e após 7 dias foram feitas análises da expressão gênica hepática por PCR em tempo real das seguintes proteínas: G6Pase, PEPCK, FAS, PPARγ, enzima málica, ChREBP, LXR, catalase, GPx, iNOS, subunidades da NADPHoxidase e PCNA. Observamos uma tendência à redução da expressão gênica da G6Pase no grupo tratado (p = 0,08). Também identificamos um aumento na expressão gênica hepática do PPARγ e FAS, dois indicadores de aumento da atividade das vias de lipogênese. Observamos um aumento na expressão gênica da iNOS, um conhecido agente indutor de resistência insulina sistêmica e hepática. Em conclusão, nossos dados indicam que o tratamento com DHEA pode estar associado com o desenvolvimento de um quadro de infiltração lipídica hepática e resistência à insulina hepática.