Neuroplasticity is essential to prevent clinical worsening despite continuing neuronal loss in several brain diseases, including multiple sclerosis (MS). The precise nature of the adaptation mechanisms taking place in MS brains, ensuring protection from disability appearance and accumulation, is however unknown. Here, we explored the hypothesis that long-term synaptic potentiation (LTP), potentially able to minimize the effects of neuronal loss by providing extra excitation of denervated neurons, is the most relevant form of adaptive plasticity in stable MS patients, and it is disrupted in progressing MS patients. We found that LTP, explored by means of transcranial magnetic theta burst stimulation over the primary motor cortex, was still possible, and even favored, in stable relapsing-remitting (RR-MS) patients, whereas it was absent in individuals with primary progressive MS (PP-MS). We also provided evidence that platelet-derived growth factor (PDGF) plays a substantial role in favoring both LTP and brain reserve in MS patients, as this molecule: (1) was reduced in the CSF of PP-MS patients, (2) enhanced LTP emergence in hippocampal mouse brain slices, (3) was associated with more pronounced LTP in RR-MS patients, and (4) was associated with the clinical compensation of new brain lesion formation in RR-MS. Our results show that brain plasticity reserve, in the form of LTP, is crucial to contrast clinical deterioration in MS. Enhancing PDGF signaling might represent a valuable treatment option to maintain brain reserve and to attenuate the clinical consequences of neuronal damage in the progressive phases of MS and in other neurodegenerative disorders.

Synaptic Plasticity and PDGF Signaling Defects Underlie Clinical Progression in Multiple Sclerosis / F., Mori; S., Rossi; Piccinin, Sonia; C., Motta; D., Mango; H., Kusayanagi; A., Bergami; V., Studer; C. G., Nicoletti; F., Buttari; F., Barbieri; N. B., Mercuri; G., Martino; R., Furlan; Nistico', ROBERT GIOVANNI; D., Centonze. - In: THE JOURNAL OF NEUROSCIENCE. - ISSN 0270-6474. - 33:49(2013), pp. 19112-19119. [10.1523/jneurosci.2536-13.2013]

Synaptic Plasticity and PDGF Signaling Defects Underlie Clinical Progression in Multiple Sclerosis

PICCININ, Sonia;NISTICO', ROBERT GIOVANNI;
2013

Abstract

Neuroplasticity is essential to prevent clinical worsening despite continuing neuronal loss in several brain diseases, including multiple sclerosis (MS). The precise nature of the adaptation mechanisms taking place in MS brains, ensuring protection from disability appearance and accumulation, is however unknown. Here, we explored the hypothesis that long-term synaptic potentiation (LTP), potentially able to minimize the effects of neuronal loss by providing extra excitation of denervated neurons, is the most relevant form of adaptive plasticity in stable MS patients, and it is disrupted in progressing MS patients. We found that LTP, explored by means of transcranial magnetic theta burst stimulation over the primary motor cortex, was still possible, and even favored, in stable relapsing-remitting (RR-MS) patients, whereas it was absent in individuals with primary progressive MS (PP-MS). We also provided evidence that platelet-derived growth factor (PDGF) plays a substantial role in favoring both LTP and brain reserve in MS patients, as this molecule: (1) was reduced in the CSF of PP-MS patients, (2) enhanced LTP emergence in hippocampal mouse brain slices, (3) was associated with more pronounced LTP in RR-MS patients, and (4) was associated with the clinical compensation of new brain lesion formation in RR-MS. Our results show that brain plasticity reserve, in the form of LTP, is crucial to contrast clinical deterioration in MS. Enhancing PDGF signaling might represent a valuable treatment option to maintain brain reserve and to attenuate the clinical consequences of neuronal damage in the progressive phases of MS and in other neurodegenerative disorders.
2013
electric stimulation; cerebrospinal fluid/physiology; magnetic resonance imaging; multiple sclerosis; signal transduction; relapsing-remitting; mice; synapses; cerebrospinal fluid/physiopathology; cerebral cortex; physiology; neuronal plasticity; electrophysiological processes; brain; animals; inbred c57bl; male; adult; disease progression; humans; chronic progressive; transcranial magnetic stimulation; platelet-derived growth factor; theta rhythm; female; evoked potentials; physiopathology; long-term potentiation
01 Pubblicazione su rivista::01a Articolo in rivista
Synaptic Plasticity and PDGF Signaling Defects Underlie Clinical Progression in Multiple Sclerosis / F., Mori; S., Rossi; Piccinin, Sonia; C., Motta; D., Mango; H., Kusayanagi; A., Bergami; V., Studer; C. G., Nicoletti; F., Buttari; F., Barbieri; N. B., Mercuri; G., Martino; R., Furlan; Nistico', ROBERT GIOVANNI; D., Centonze. - In: THE JOURNAL OF NEUROSCIENCE. - ISSN 0270-6474. - 33:49(2013), pp. 19112-19119. [10.1523/jneurosci.2536-13.2013]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/555311
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