High-frequency repetitive magnetic stimulation rescues ischemia-injured neurons through modulation of glial-derived neurotrophic factor present in the astrocyte's secretome.

Due to its ability to improve the most frequent clinical sequelae left by ischemia, repetitive transcranial magnetic stimulation has been considered a promising therapeutic strategy for stroke. Those improvements are associated with changes in neurons and their synaptic liaisons. However, the hypothesis that this technique modulates astrocytes, potentiating their neuroprotective capabilities, was also raised. This study aims to identify the effects triggered by high-frequency repetitive magnetic stimulation (HF-rMS) on astrocytes that contribute to its neuroprotective effects. Neuron-glia and astrocyte cortical cultures subject to oxygen and glucose deprivation were used as an in vitro model of ischemia. Neuroprotection promoted by HF-rMS was evaluated by analysis of markers of neuronal activity and morphometric analysis of neurons. Glial reactivity was determined by immunocytochemistry. The levels of growth factors in the astrocyte-conditioned medium (CM) were assessed through a Growth Factor Array and glial-derived neurotrophic factor (GDNF) expression was analyzed by RT-PCR and Western blot. Our results show that neurons injured by ischemia can be rescued through the modulation of astrocytes by HF-rMS. This modulation helps to maintain the number and length of neurites and increases the number of neurons expressing ERK1/2 and c-Fos. Analysis of the astrocyte-CM showed that HF-rMS stimulated the release of several trophic factors by astrocytes. Moreover, GDNF was one of the released factors that contributed to the recovery mechanisms triggered by HF-rMS. Our results show that modulation of astrocytes by HF-rMS effectively rescues neurons injured by ischemia and suggest that by targeting astrocytes this approach can also be used to promote neuroprotection in other brain lesions.

Endogenous GDNF Is Unable to Halt Dopaminergic Injury Triggered by Microglial Activation.

Overactivation of microglial cells seems to play a crucial role in the degeneration of dopaminergic neurons occurring in Parkinson's disease. We have previously demonstrated that glial cell line-derived neurotrophic factor (GDNF) present in astrocytes secretome modulates microglial responses induced by an inflammatory insult. Therefore, astrocyte-derived soluble factors may include relevant molecular players of therapeutic interest in the control of excessive neuroinflammatory responses. However, in vivo, the control of neuroinflammation is more complex as it depends on the interaction between different types of cells other than microglia and astrocytes. Whether neurons may interfere in the astrocyte-microglia crosstalk, affecting the control of microglial reactivity exerted by astrocytes, is unclear. Therefore, the present work aimed to disclose if the control of microglial responses mediated by astrocyte-derived factors, including GDNF, could be affected by the crosstalk with neurons, impacting GDNF's ability to protect dopaminergic neurons exposed to a pro-inflammatory environment. Also, we aimed to disclose if the protection of dopaminergic neurons by GDNF involves the modulation of microglial cells. Our results show that the neuroprotective effect of GDNF was mediated, at least in part, by a direct action on microglial cells through the GDNF family receptor α-1. However, this protective effect seems to be impaired by other mediators released in response to the neuron-astrocyte crosstalk since neuron-astrocyte secretome, in contrast to astrocytes secretome, was unable to protect dopaminergic neurons from the injury triggered by lipopolysaccharide-activated microglia. Supplementation with exogenous GDNF was needed to afford protection of dopaminergic neurons exposed to the inflammatory environment. In conclusion, our results revealed that dopaminergic protective effects promoted by GDNF involve the control of microglial reactivity. However, endogenous GDNF is insufficient to confer dopaminergic neuron protection against an inflammatory insult. This reinforces the importance of further developing new therapeutic strategies aiming at providing GDNF or enhancing its expression in the brain regions affected by Parkinson's disease.

The effects of a high dosage of creatine and caffeine supplementation on the lean body mass composition of rats submitted to vertical jumping training.

BACKGROUND: The influences of creatine and caffeine supplementation associated with power exercise on lean body mass (LBM) composition are not clear. The purpose of this research was to determine whether supplementation with high doses of creatine and caffeine, either solely or combined, affects the LBM composition of rats submitted to vertical jumping training. METHODS: Male Wistar rats were randomly divided into 8 groups: Sedentary (S) or Exercised (E) [placebo (Pl), creatine (Cr), caffeine (Caf) or creatine plus caffeine (CrCaf)]. The supplemented groups received creatine [load: 0.430 g/kg of body weight (BW) for 7 days; and maintenance: 0.143 g/kg of BW for 35 days], caffeine (15 mg/kg of BW for 42 days) or creatine plus caffeine. The exercised groups underwent a vertical jump training regime (load: 20 - 50% of BW, 4 sets of 10 jumps interspersed with 1 min resting intervals), 5 days/wk, for 6 weeks. LBM composition was evaluated by portions of water, protein and fat in the rat carcass. Data were submitted to ANOVA followed by the Tukey post hoc test and Student's t test. RESULTS: Exercised animals presented a lower carcass weight (10.9%; P = 0.01), as compared to sedentary animals. However, no effect of supplementation was observed on carcass weight (P > 0.05). There were no significant differences among the groups (P > 0.05) for percentage of water in the carcass. The percentage of fat in the group SCr was higher than in the groups SCaf and ECr (P < 0.05). A higher percentage of protein was observed in the groups EPl and ECaf when compared to the groups SPl and SCaf (P < 0.001). The percentage of fat in the carcass decreased (P < 0.001), while those of water and protein increased (P < 0.05) in exercised animals, compared to sedentary animals. Caffeine groups presented reduced percentage of fat when compared to creatine supplemented groups (P < 0.05). CONCLUSIONS: High combined doses of creatine and caffeine does not affect the LBM composition of either sedentary or exercised rats, however, caffeine supplementation alone reduces the percentage of fat. Vertical jumping training increases the percentages of water and protein and reduces the fat percentage in rats.