The motor cortex and spinal cord possess the remarkable ability to alter structure and function in response to differential motor training. Here we review the evidence that the corticospinal system is not only plastic but that the nature and locus of this plasticity is dictated by the specifics of the motor experience. Skill training induces synaptogenesis, synaptic potentiation, and reorganization of movement representations within motor cortex. Endurance training induces angiogenesis in motor cortex, but it does not alter motor map organization or synapse number. Strength training alters spinal motoneuron excitability and induces synaptogenesis within spinal cord, but it does not alter motor map organization. All three training experiences induce changes in spinal reflexes that are dependent on the specific behavioral demands of the task. These results demonstrate that the acquisition of skilled movement induces a reorganization of neural circuitry within motor cortex that supports the production and refinement of skilled movement sequences. We present data that suggest increases in strength may be mediated by an increased capacity for activation and/or recruitment of spinal motoneurons while the increased metabolic demands associated with endurance training induce cortical angiogenesis. Together these results show the robust pattern of anatomic and physiological plasticity that occurs within the corticospinal system in response to differential motor experience. The consequences of such distributed, experience-specific plasticity for the encoding of motor experience by the motor system are discussed.
Traumatic brain injury (TBI) greatly increases the risk for a number of mental health problems and is one of the most common causes of medically intractable epilepsy in humans. Several models of TBI have been developed to investigate the relationship between trauma, seizures, and epilepsy-related changes in neural circuit function. These studies have shown that the brain initiates immediate neuronal and glial responses following an injury, usually leading to significant cell loss in areas of the injured brain. Over time, long-term changes in the organization of neural circuits, particularly in neocortex and hippocampus, lead to an imbalance between excitatory and inhibitory neurotransmission and increased risk for spontaneous seizures. These include alterations to inhibitory interneurons and formation of new, excessive recurrent excitatory synaptic connectivity. Here, we review in vivo models of TBI as well as key cellular mechanisms of synaptic reorganization associated with post-traumatic epilepsy (PTE). The potential role of inflammation and increased blood–brain barrier permeability in the pathophysiology of PTE is also discussed. A better understanding of mechanisms that promote the generation of epileptic activity versus those that promote compensatory brain repair and functional recovery should aid development of successful new therapies for PTE.
Post-traumatic epilepsy (PTE) is one consequence of traumatic brain injury (TBI). A prominent cell signaling pathway activated in animal models of both TBI and epilepsy is the mammalian target of rapamycin (mTOR). Inhibition of mTOR with rapamycin has shown promise as a potential modulator of epileptogenesis in several animal models of epilepsy, but cellular mechanisms linking mTOR expression and epileptogenesis are unclear. In this study, the role of mTOR in modifying functional hippocampal circuit reorganization after focal TBI induced by controlled cortical impact (CCI) was investigated. Rapamycin (3 or 10 mg/kg), an inhibitor of mTOR signaling, was administered by intraperitoneal injection beginning on the day of injury and continued daily until tissue collection. Relative to controls, rapamycin treatment reduced dentate granule cell area in the hemisphere ipsilateral to the injury two weeks post-injury. Brain injury resulted in a significant increase in doublecortin immunolabeling in the dentate gyrus ipsilateral to the injury, indicating increased neurogenesis shortly after TBI. Rapamycin treatment prevented the increase in doublecortin labeling, with no overall effect on Fluoro-Jade B staining in the ipsilateral hemisphere, suggesting that rapamycin treatment reduced posttraumatic neurogenesis but did not prevent cell loss after injury. At later times post-injury (8–13 weeks), evidence of mossy fiber sprouting and increased recurrent excitation of dentate granule cells was detected, which were attenuated by rapamycin treatment. Rapamycin treatment also diminished seizure prevalence relative to vehicle-treated controls after TBI. Collectively, these results support a role for adult neurogenesis in PTE development and suggest that suppression of epileptogenesis by mTOR inhibition includes effects on post-injury neurogenesis.
Changes in functional GABAAR signaling in hippocampus have previously been evaluated using pre-clinical animal models of either diffuse brain injury or extreme focal brain injury that precludes measurement of cells located ipsilateral to injury. As a result, there is little information about the status of functional GABAAR signaling in dentate granule cells (DGCs) located ipsilateral to focal brain injury, where significant cellular changes have been documented. We used whole-cell patch-clamp recordings from hippocampal slices to measure changes in GABAARs in dentate granule cells (DGCs) at 1-2, 3-5, and 8-13 weeks after controlled cortical impact (CCI) brain injury. Synaptic and tonic GABAAR currents (ITonicGABA) were measured in DGCs at baseline conditions and during application of the GABAAR agonist 4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridine-3-ol hydrochloride (THIP) to assess in the function of δ subunit-containing GABAARs. DGCs ipsilateral to CCI exhibited no changes in the amplitude of resting ITonicGABA relative to DGCs after sham-injury or contralateral to CCI. In contrast, there was a significant reduction in the THIP-evoked ITonicGABA in DGCs ipsilateral to CCI at both time-points. Tonic GABAergic inhibition of DGCs ipsilateral to injury also exhibited reduced responsiveness to the neurosteroid THDOC. ITonicGABA in DGCs ipsilateral to CCI did not exhibit a change in sensitivity to L655,708, an inverse agonist with selectivity for α5 subunit-containing GABAARs, suggesting a lack of functional change in GABAARs containing this subunit. At the 8-13 week time-point, gene expression of GABAAR subunits expected to contribute to ITonicGABA (i.e., α4, α5 and δ) was not significantly altered by CCI injury in isolated dentate gyrus. Collectively, these results demonstrate enduring functional changes in ITonicGABA in DGCs ipsilateral to focal brain injury that occur independent of altered gene expression.
The results indicate that although both focal and distributed forms of CS/RT promote motor map reorganization only the distributed form of CS/RT enhances motor performance with rehabilitation.
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