Acute salt loading induces sympathetic nervous system overdrive in mice lacking salt-inducible kinase 1 (SIK1).

Loss of salt-inducible kinase 1 (SIK1) triggers an increase in blood pressure (BP) upon a chronic high-salt intake in mice. Here, we further addressed the possible early mechanisms that may relate to the observed rise in BP in mice lacking SIK1. SIK1 knockout (sik1-/-) and wild-type (sik1+/+) littermate mice were challenged with either a high-salt (8% NaCl) or control (0.3% NaCl) diet for 7 days. Systolic BP was significantly increased in sik1-/- mice after 7 days of high-salt diet as compared with sik1+/+ mice and to sik1-/- counterparts on a control diet. The renin-angiotensin-aldosterone system and the sympathetic nervous system were assayed to investigate possible causes for the increase in BP in sik1-/- mice fed a 7-day high-salt diet. Although no differences in serum renin and angiotensin II levels were observed, a reduction in aldosterone serum levels was observed in mice fed a high-salt diet. Urinary L-DOPA and noradrenaline levels were significantly increased in sik1-/- mice fed a high-salt diet as compared with sik1-/- mice on a control diet. Similarly, the activity of dopamine ß-hydroxylase (DßH), the enzyme that converts dopamine to noradrenaline, was significantly increased in the adrenal glands of sik1-/- mice on a high-salt intake compared with sik1+/+ and sik1-/- mice on a control diet. Treatment with etamicastat (50 mg/kg/day), a peripheral reversible DßH inhibitor, administered prior to high-salt diet, completely prevented the systolic BP increase in sik1-/- mice. In conclusion, SIK1 activity is necessary to prevent the development of salt-induced high blood pressure and associated SNS overactivity.

Role of Neurotrophic Factors in Parkinson's Disease.

Parkinson's disease is an age-associated progressive neurodegenerative disorder that has gained crescent social and economic impact due to the aging of the western society. All current therapies are symptomatic and fail to reverse or halt the progression of dopaminergic neurons loss. The discovery of the capability of neurotrophic factors to protect these neurons lead numerous research groups to focus their efforts in developing therapies aiming at promoting the control of Parkinson´s disease through the delivery of neurotrophic factors to the brain or by boosting their endogenous levels. Both strategies were successful in inducing protection of dopaminergic neurons and motor recovery in preclinical models of the disease. Contrariwise, very limited success was obtained in clinical studies, where glial cell line-derived neurotrophic factor and neurturin were the neurotrophic factors of choice for Parkinson's disease therapy. These drawbacks motivate the development of novel forms of delivery or the modification of the injected molecules aiming at providing a more stable and effective administration with improved diffusion in the target tissue, and without the immune responses observed in the earliest clinical studies. Although promising results were obtained with some of these new approaches performed in experimental models of the disease, they were not yet tested in human studies. In this review, we present the current knowledge on neurotrophic factors and their role in Parkinson's disease, focusing on the strategies that have been developed to increase their levels in target areas of the brain to achieve protection of dopaminergic neurons and motor behaviour recovery.

GPER: A new tool to protect dopaminergic neurons?

Parkinson's disease (PD) is characterized by a selective degeneration of nigrostriatal dopaminergic pathway. Epidemiological studies revealed a male predominance of the disease that has been attributed to the female steroid hormones, mainly the estrogen. Estrogen neuroprotective effects have been shown in several studies, however the mechanisms responsible by these effects are still unclear. Previous data from our group revealed that glial cell line-derived neurotrophic factor (GDNF) is crucial to the dopaminergic protection provided by 17ß-estradiol, and also suggest that the intracellular estrogen receptors (ERs) are not required for that neuroprotective effects. The present study aimed to investigate the contribution of the G protein-coupled ER (GPER) activation in estrogen-mediated dopaminergic neuroprotection against an insult induced by 1-methyl-4-phenylpyridinium (MPP(+)), and whether GPER neuroprotective effects involve the regulation of GDNF expression. Using primary mesencephalic cultures, we found that GPER activation protects dopaminergic neurons from MPP(+) toxicity in an extent similar to the promoted by a 17ß-estradiol. Moreover, GPER activation promotes an increase in GDNF levels. Both, GDNF antibody neutralization or RNA interference-mediated GDNF knockdown prevented the GPER-mediated dopaminergic protection verified in mesencephalic cultures challenged with MPP(+). Overall, these results revealed that G1, a selective agonist of GPER, is able to protect dopaminergic neurons and that GDNF overexpression is a key feature to GPER induced the neuroprotective effects.

Astrocyte-derived GDNF is a potent inhibitor of microglial activation.

Neuroinflammation is recognized as a major factor in Parkinson's disease (PD) pathogenesis and increasing evidence propose that microglia is the main source of inflammation contributing to the dopaminergic degeneration observed in PD. Several studies suggest that astrocytes could act as physiological regulators preventing excessive microglia responses. However, little is known regarding how astrocytes modulate microglial activation. In the present study, using Zymosan A-stimulated midbrain microglia cultures, we showed that astrocytes secrete factors capable of modulating microglial activation, namely its phagocytic activity and the production of reactive oxygen species since both parameters were highly diminished in cells incubated with astrocytes conditioned media (ACM). Glial cell line-derived neurotrophic factor (GDNF), cerebral dopamine neurotrophic factor (CDNF) and brain-derived neurotrophic factor (BDNF), known to have a neuroprotective role in the nigrostriatal system, are among the candidates to be astrocyte-secreted molecules involved in the modulation of microglial activation. The effect of ACM on Zymosan A-induced microglial activation was abolished when the GDNF present in the ACM was abrogated using a specific antibody, but not when ACM was neutralized with anti-CDNF, anti-BDNF or with a heat-inactivated GDNF antibody. In addition, media conditioned by astrocytes silenced for GDNF were not able to prevent microglial activation, whereas supplementation of non-conditioned media with GDNF prevented the activation of microglia evoked by Zymosan A. Taken together, these results indicate that astrocyte-derived GDNF plays a major contribution to the control of midbrain microglial activation, suggesting that GDNF can protect from neurodegeneration through the inhibition of neuroinflammation.