A new tool to sense pH changes at the neuromuscular junction synaptic cleft

Synaptic transmission triggers transient acidification of the synaptic cleft. Recently, it has been shown that pH affects the opening of postsynaptic channels and therefore the production of tools that allow to study these behaviors should result of paramount value. We fused α-bungarotoxin, a neurotoxin derived from the snake Bungarus multicinctus that binds irreversibly to the acetylcholine receptor extracellular domain, to the pH sensitive GFP Super Ecliptic pHluorin, and efficiently expressed it in Pichia pastoris. This sensor allows synaptic changes in pH to be measured without the need of incorporating transgenes into animal cells. Here, we show that incubation of the mouse levator auris muscle with a solution containing this recombinant protein is enough to fluorescently label the endplate post synaptic membrane. Furthermore, we could physiologically alter and measure post synaptic pH by evaluating changes in the fluorescent signal of pHluorin molecules bound to acetylcholine receptors. In fact, using this tool we were able to detect a drop in 0.01 to 0.05 pH units in the vicinity of the acetylcholine receptors following vesicle exocytosis triggered by nerve electrical stimulation. Further experiments will allow to learn the precise changes in pH during and after synaptic activation.

AMP-activated Protein Kinase Controls Immediate Early Genes Expression Following Synaptic Activation Through the PKA/CREB Pathway

Long-term memory formation depends on the expression of immediate early genes (IEGs). Their expression, which is induced by synaptic activation, is mainly regulated by the 3′,5′-cyclic AMP (cAMP)-dependent protein kinase/cAMP response element binding protein (cAMP-dependent protein kinase (PKA)/ cAMP response element binding (CREB)) signaling pathway. Synaptic activation being highly energy demanding, neurons must maintain their energetic homeostasis in order to successfully induce long-term memory formation. In this context, we previously demonstrated that the expression of IEGs required the activation of AMP-activated protein kinase (AMPK) to sustain the energetic requirements linked to synaptic transmission. Here, we sought to determine the molecular mechanisms by which AMPK regulates the expression of IEGs. To this end, we assessed the involvement of AMPK in the regulation of pathways involved in the expression of IEGs upon synaptic activation in differentiated primary neurons. Our data demonstrated that AMPK regulated IEGs transcription via the PKA/CREB pathway, which relied on the activity of the soluble adenylyl cyclase. Our data highlight the interplay between AMPK and PKA/CREB signaling pathways that allows synaptic activation to be transduced into the expression of IEGs, thus exemplifying how learning and memory mechanisms are under metabolic control.

AMP-activated protein kinase is essential for the maintenance of energy levels during synaptic activation

While accounting for 2% of the total body mass, the brain is the organ that consumes the most energy. Although it is widely acknowledged that neuronal energy metabolism is tightly regulated, the mechanism how neurons meet their energy demand to sustain synaptic transmission remains poorly studied. Here we provide substantial evidence that the AMP-activated protein kinase (AMPK) plays a leading role in this process. Our results show that following synaptic activation, AMPK activation is required to sustain neuronal energy levels particularly through mitochondrial respiration. Further, our studies revealed that this metabolic plasticity regulated by AMPK is required for the expression of immediate early genes, synaptic plasticity and memory formation. These findings are important in the context of neurodegenerative disorders, as AMPK deregulation as it is observed in Alzheimer’s disease, impairs the metabolic response to synaptic activation. Altogether, our data provides the proof of concept that AMPK is an essential player in the regulation of neuroenergetic metabolism plasticity induced in response to synaptic activation.