Neurodegenerative diseases represent a large group of disorders characterized by gradual loss of neurons and functions of the central nervous systems. Their course is usually severe, leading to high morbidity and subsequent inability of patients to independent functioning. Vast majority of neurodegenerative diseases is currently untreatable, and only some symptomatic drugs are available which efficacy is usually very limited. To develop novel therapies for this group of diseases, it is crucial to understand their pathogenesis and to recognize factors which can influence the disease course. One of cellular structures which dysfunction appears to be relatively poorly understood in the light of neurodegenerative diseases is tubulin cytoskeleton.

Mitochondrial calcium regulates neuronal metabolism and memory.

Brain metabolism is important for long-term memories (LTMs) and various brain functions, Although it is well known that impairing neuronal metabolism limits brain performance, it is not clear if expanding the metabolic capacity of neurons boosts brain function.

In this study, the authors demonstrate that increasing mitochondrial metabolism can enhance LTM formation in flies and mice.

The authors increase mitochondrial Ca2+ by knocking down the mitochondrial Ca2+ exporter Letm1 and demonstrate over-activation of mitochondrial metabolism in neurons of central memory circuits, leading to improved LTM storage. sciencenewshighlights Science Mission https://sciencemission.com/Mitochondrial-Ca2-efflux

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Boosting mitochondrial metabolism in neurons in central memory circuits by enhancing Ca2+ retention in the mitochondrial matrix is shown to improve long-term memory formation in flies and mice.

Many patients suffer from epilepsy that cannot be controlled by current medications. Surgical removal of epileptogenic brain regions is effective in only about half of cases, and not all patients are eligible for the procedure. For these individuals, therapeutic options remain severely limited. Researchers from the Paris Brain Institute and the Institut du Fer à Moulin in Paris have now taken an important step forward: they have identified two molecules capable of reducing seizure frequency by targeting a mechanism that has so far received little attention. Their findings are published in Proceedings of the National Academy of Sciences.

For the brain to function normally, it must continuously regulate its electrical activity. One of the key mechanisms involved is GABAergic signaling, a natural inhibitory system that controls neuronal activity and prevents the electrical bursts that characterize epileptic seizures. This braking system depends on a delicate balance: the concentration of chloride inside neurons.

An ion transporter known as KCC2 is responsible for removing excess chloride from nerve cells. When it functions poorly—as observed in many neurological disorders, including mesial temporal lobe epilepsy, the most common form of focal epilepsy in adults—chloride accumulates inside neurons. As a result, GABAergic signals, instead of inhibiting neuronal activity, can paradoxically excite it.