Lactate entrance into the brain facilities adipose tissue lipolysis during exercise via circulating calcitonin gene-related peptide.

Objectives: We assessed the relationships between CGRP, lactate and fat regulation.Methods: We evaluated the effect of intracerebroventricular (i.c.v.) injection of lactate and acute exercise on brain CGRP expression, and its concentration in serum/cerebrospinal fluid (SCF) in rats.Results: Injection of lactate up-regulated CGRP expression in the cortex and CSF and activated p38-mitogen-activated protein kinases (p38-MAPK) pathway. Co-injection of lactate and sb203580, deterred lactate-induced up-regulation of CGRP in the brain and CSF. Exercise increased the CGRP expression in the brain and CSF and up-regulated fat metabolism. Inhibition of lactate entrance into the brain using alpha-cyano-4-hydroxycinnamate (4-CIN) diminished exercise-induced CGRP up-regulation in the brain and CSF. Reducing the circulating blood lactate by pre-treatment of the animals with dichloroacetate (DCA) had no effect on exercise-induced increase in CGRP expression or fat metabolism during exercise.Conclusions: lactate probably acts as one of a signalling molecule in the brain to regulate fat metabolism during exercise.

Comparison of preventive and therapeutic effects of continuous exercise on acute lung injury induced with methotrexate.

Methotrexate (Mtx) is used to treat various diseases, including cancer, arthritis and other rheumatic diseases. However, it induces oxidative stress and pulmonary inflammation by stimulating production of reactive oxygen species and cytokines. Considering the positive effects of physical activity, our goal was to investigate the preventive and therapeutic role of continuous training (CT) on Mtx-induced lung injury in rats. The rats were divided into five groups of 14 animals: a control group (C); a continuous exercise training group (CT; healthy rats that experienced CT); an acute lung injury with Mtx group (ALI); a pretreatment group with CT (the rats experienced CT before ALI induction), and a post-treatment group with CT (the rats experienced CT after ALI induction). One dose of 20 mg/kg Mtx intraperitoneal was administered in the Mtx and training groups. Forty-eight hours after the last exercise session all rats were sacrificed. According to our results, the levels of tumour necrosis factor-α (TNF-α), malondialdehyde (MDA), myeloperoxidase (MPO), GATA binding protein 3 (GATA3) and caspase-3 in the ALI group significantly increased compared to the control group, and the levels of superoxide dismutase (SOD), glutathione peroxidase (GPX), total antioxidant capacity (TAC), interleukin-10 (IL-10), forkhead box protein 3 (FOXP3), and T-bet decreased. In contrast, compared to the acute lung injury group, pretreatment and treatment with CT reduced TNF-α, MDA, MPO, GATA3 and caspase-3 and increased SOD, GPX, TAC, IL-10, FOXP3 and T-bet levels. The effects of CT pretreatment were more significant than the effects of CT post-treatment. Continuous exercise training effectively reduced oxidative stress and inflammatory cytokines and ameliorated Mtx-induced injury, and the effects of CT pretreatment were more significant than the effects of CT post-treatment. NEW FINDINGS: What is the central question of this study? Considering the high prevalence of lung injury in society, does exercise as a non-pharmacological intervention have ameliorating effects on lung injury? What is the main finding and its importance? Exercise can have healing effects on the lung after pulmonary injury through reducing inflammation, oxidative stress and apoptosis. Considering the lower side effects of exercise compared to drug treatments, the results of this study may be useful in the future.

Inhibitory effects of selected antibiotics on the activities of α-amylase and α-glucosidase: In-vitro, in-vivo and theoretical studies.

Antibiotics are effective drugs that are used to treat infectious diseases either by killing bacteria or slowing down their growth. The well-adapted structural features of antibiotics for the inhibition/activation of enzymes include several available hydrogen bond (H-bond) acceptors and donors, flexible backbone and hydrophobic nature. The substrates of α-amylase and α-glucosidase, known as key absorbing enzymes, have functional groups (OH groups) rembling antibiotics. Given the possibility of developing in diabetics and the significant association between diabetes and infection, the present study was conducted to investigate the influences of tetracycline (TET), kanamycin (KANA), lincomycin (LIN), erythromycin (ERM) and azithromycin (AZM) on α-glucosidase and α-amylase activities with calculating IC50 and Ki values. Also, the efficacy of antibiotics after oral administration was evaluated by analysis of blood glucose concentrations in rats, as well as a molecular docking analysis was explored. α-glucosidase and α-amylase activities were inhibited in a dose dependent fashion by TET with an IC50 of 38.7 ±â€¯1.4 and 47.8 ±â€¯3.2 µM respectively, by KANA with an IC50 of 46.2 ±â€¯1.6 and 65.1 ±â€¯1.6, by LIN with an IC50 of 59.1 ±â€¯2.1 and 51.3 ±â€¯4.1, by ERM with an IC50 of 94.9 ±â€¯4.7 and 65.7 ±â€¯3.8 and by AZM with an IC50 of 69.4 ±â€¯4.4 and 103.6 ±â€¯6.2. Moreover, the Ki values of TET were calculated as 4.4 ±â€¯0.6 and 8.4 ±â€¯0.8 µM for α-glucosidase and α-amylase in a competitive-mode and mixed-mode inhibition. In addition, to communicate with the active site of α-glucosidase and α-amylase respectively, TET presented a binding energy of -9.8 and -8.8 kcal/mol, KANA -7.9 and -7.1, LIN -7.8 and -6.7, ERM -6.8 and -6.4, and AZM -6.4 and -7.5 kcal/mol. In-vivo studies also suggested a decrease in the blood glucose concentration after administering TET compared to the positive controls (P < 0.01). The results obtained from the present research can therefore help the scientific community explore the possible interconnection between the clinical side-effects of antibiotics and their α-glucosidase and α-amylase inhibitory properties, as the target enzymes in hypoglycemia conditions.