Abstract
Astrocytes have emerged as crucial regulators of neuronal network activity, synapse formation, and underlying behavioral and cognitive processes. Despite some pathways have been identified, the communication between astrocytes and neurons remains to be completely elucidated. Unraveling this communication is crucial to design potential treatments for neurological disorders like temporal lobe epilepsy (TLE). The BDNF and TrkB molecules have emerged as very promising therapeutic targets. However, their modulation can be accompanied by several off-target effects such as excitotoxicity in case of uncontrolled upregulation or dementia, amnesia, and other memory disorders in case of downregulation. Here, we show that BDNF and TrkB from astrocytes modulate neuronal dysfunction in TLE models. First, conditional overexpression of BDNF from astrocytes worsened the phenotype in the lithium-pilocarpine mouse model. Our evidences pointed out to the astrocytic pro-BDNF isoform as a major player of this altered phenotype. Conversely, specific genetic deletion of BDNF in astrocytes prevented the increase in the number of firing neurons and the global firing rate in an in vitro model of TLE. Regarding to the TrkB, we generated mice with a genetic deletion of TrkB specifically in hippocampal neurons or astrocytes. Interestingly, both lines displayed neuroprotection in the lithium-pilocarpine model but only the mice with genetic deletion of TrkB in astrocytes showed significantly preserved spatial learning skills. These data identify the astrocytic BDNF and TrkB molecules as promising therapeutic targets for the treatment of TLE.
Highlights
Correct function of neuronal networks depends on an appropriate modulation by astrocytes[1]
Since it has been widely demonstrated that BDNF is expressed and released by astrocytes[20,21,22,23], we aimed to study the role of the neurotrophin produced by astrocytes in a temporal lobe epilepsy (TLE) model by using wild-type (WT) mice and the pGFAP-BDNF transgenic mice as a gain-of-BDNFfunction approach
We observed in the openfield (OF) paradigm that WT mice treated with pilocarpine displayed a significant increase in their pathlength compared to WT and pGFAP-BDNF mice treated with vehicle (Fig. 1d)
Summary
Correct function of neuronal networks depends on an appropriate modulation by astrocytes[1]. Activated astrocytes provide both excitatory and inhibitory effects on neighboring neurons[2]. Astrocytes can modulate neuronal activity and, in turn, neurons exert functional changes in astrocytes upon neural activity such as modifications in gene expression, gliotransmitter release and intracellular calcium signals[3,4,5,6]. Recent literature has shown that BDNF and TrkB are expressed in both neurons and astrocytes[7]. This expression pattern suggests that the BDNF–TrkB pathway could be a core system modulating astrocyte–neuron reciprocal communication. ProBDNF can activate p75NTR to induce neurotoxicity
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