Intracellular calcium signals in the surround of rat visual cortex lesions

Altered Sensitivity to Motion of Area MT Neurons Following Long-Term V1 Lesions

Primates with primary visual cortex (V1) damage often retain residual motion sensitivity, which is hypothesized to be mediated by middle temporal area (MT). MT neurons continue to respond to stimuli shortly after V1 lesions; however, experimental and clinical studies of lesion-induced plasticity have shown that lesion effects can take several months to stabilize. It is unknown what physiological changes occur in MT and whether neural responses persist long after V1 damage. We recorded neuronal responses in MT to moving dot patterns in adult marmoset monkeys 6-12 months after unilateral V1 lesions. In contrast to results obtained shortly after V1 lesions, we found that fewer MT neurons were direction selective, including neurons expected to still receive projections from remaining parts of V1. The firing rates of most cells increased with increases in motion strength, regardless of stimulus direction. Furthermore, firing rates were higher and more variable than in control MT cells. To test whether these observations could be mechanistically explained by underlying changes in neural circuitry, we created a network model of MT. We found that a local imbalance of inhibition and excitation explained the observed firing rate changes. These results provide the first insights into functional implications of long-term plasticity in MT following V1 lesions.

Laser Lesion in the Mouse Visual Cortex Induces a Stem Cell Niche-Like Extracellular Matrix, Produced by Immature Astrocytes

The mammalian central nervous system (CNS) is characterized by a severely limited regeneration capacity. Comparison with lower species like amphibians, which are able to restore even complex tissues after damage, indicates the presence of an inhibitory environment that restricts the cellular response in mammals. In this context, signals provided by the extracellular matrix (ECM) are important regulators of events like cell survival, proliferation, migration, differentiation or neurite outgrowth. Therefore, knowledge of the post-lesional ECM and of cells that produce these factors might support development of new treatment strategies for patients suffering from traumatic brain injury and other types of CNS damage. In the present study, we analyzed the surround of focal infrared laser lesions of the adult mouse visual cortex. This lesion paradigm avoids direct contact with the brain, as the laser beam passes the intact bone. Cell type-specific markers revealed a distinct spatial distribution of different astroglial subtypes in the penumbra after injury. Glial fibrillary acidic protein (GFAP) as marker for reactive astrocytes was found broadly up-regulated, whereas the more immature markers vimentin and nestin were only expressed by a subset of cells. Dividing astrocytes could be identified via the proliferation marker Ki-67. Different ECM molecules, among others the neural stem cell-associated glycoprotein tenascin-C and the DSD-1 chondroitin sulfate epitope, were found on astrocytes in the penumbra. Wisteria floribunda agglutinin (WFA) and aggrecan as markers for perineuronal nets, a specialized ECM limiting synaptic plasticity, appeared normal in the vicinity of the necrotic lesion core. In sum, expression of progenitor markers by astrocyte subpopulations and the identification of proliferating astrocytes in combination with an ECM that contains components typically associated with neural stem/progenitor cells suggest that an immature cell fate is facilitated as response to the injury.

Focal cortical lesions induce bidirectional changes in the excitability of fast spiking and non fast spiking cortical interneurons

A physiological brain function requires neuronal networks to operate within a well-defined range of activity. Indeed, alterations in neuronal excitability have been associated with several pathological conditions, ranging from epilepsy to neuropsychiatric disorders. Changes in inhibitory transmission are known to play a key role in the development of hyperexcitability. However it is largely unknown whether specific interneuronal subpopulations contribute differentially to such pathological condition. In the present study we investigated functional alterations of inhibitory interneurons embedded in a hyperexcitable cortical circuit at the border of chronically induced focal lesions in mouse visual cortex. Interestingly, we found opposite alterations in the excitability of non fast-spiking (Non Fs) and fast-spiking (Fs) interneurons in acute cortical slices from injured animals. Non Fs interneurons displayed a depolarized membrane potential and a higher frequency of spontaneous excitatory postsynaptic currents (sEPSCs). In contrast, Fs interneurons showed a reduced sEPSCs amplitude. The observed downscaling of excitatory synapses targeting Fs interneurons may prevent the recruitment of this specific population of interneurons to the hyperexcitable network. This mechanism is likely to seriously affect neuronal network function and to exacerbate hyperexcitability but it may be important to protect this particular vulnerable population of GABAegic neurons from excitotoxicity.

Two faces of calcium activation after optic nerve trauma: life or death of retinal ganglion cells in vivo depends on calcium dynamics

Calcium elevations after neurotrauma are not only implicated in cell death but may contribute to adaptive plasticity. We now wished to resolve this contradiction by following calcium dynamics after optic nerve crush in vivo. Adult rats received no injury (n = 5), unilateral mild (n = 10) or moderate optic nerve crush (n = 10) (ONC), or axotomy (n = 5). Before surgery, retinal ganglion cells (RGCs) were retrogradely labelled with Oregon Green BAPTA-dextran, a fluorescent calcium marker. Calcium-related fluorescence intensity (FI) was repeatedly measured in individual RGCs in vivo using the in vivo confocal neuroimaging (ICON) method. Four different RGC types were found. Normal RGCs without FI change were found in sham rats and also in both ONC groups. RGCs with mild damage were seen only after mild ONC, showing an initial calcium depression of 26% at day 4 followed by a 169% increase 15 days after ONC. RGCs with moderate damage were found only after moderate ONC and showed calcium hypoactivation followed by a slower return toward baseline and a delayed calcium increase of 72% above baseline. Sixty to sixty-five per cent of the RGCs in both ONC groups and all RGCs in the axotomy group died within 6 days following a fast and massive calcium increase of 316% with a concomitant 156% soma size increase. In conclusion rapid calcium elevation leads to cell death, while an initial calcium depression followed by a delayed and moderate calcium hyperactivation is associated with cell survival. We propose that immediate, massive calcium activation is maladaptive whereas delayed and moderate hyperactivation of surviving cells is adaptive. Implications for pharmacotherapy are discussed.

Lesion-induced enhancement of LTP in rat visual cortex is mediated by NMDA receptors containing the NR2B subunit

There is emerging evidence that injury of the cerebral cortex is followed by processes of enhanced neuroplasticity. In the present study, we investigate the functional properties of NMDA receptors (NMDARs) in the surround of focal lesions with recordings of extracellular field potentials (FPs) in acute slices of rat visual cortex at survival times of 2-6 days. FPs were recorded in cortical layer III lateral to the lesion, while long-term potentiation (LTP) was induced by theta-burst stimulation (TBS) in layer IV. The predominantly AMPA receptor-mediated FPs displayed a significantly enhanced LTP in the surround of the lesion at distances of 2-3.2 mm. The LTP was completely blocked by the NMDAR antagonist D-AP5. Ifenprodil, an antagonist of NMDARs containing the NR2B subunit, only slightly affected the LTP in slices from sham-operated animals, but significantly reduced the LTP in slices from lesioned rats. We quantitatively analysed the proportion of NMDARs containing the NR2B subunit after lesions by applying ifenprodil to pharmacologically isolated NMDAR-FPs. The NR2B antagonist reduced the NMDAR-FPs significantly more strongly at distances of 2.0-3.2 mm from the border of the lesion. This indicates that the early phase of increased synaptic long-term plasticity in the surround of cortical lesions is accompanied by an up-regulation of NMDARs containing the NR2B subunit.

Changes in intracellular calcium transients and LTP in the surround of visual cortex lesions in rats

Injury and loss of neurons are observed in the center of a cerebral cortical lesion. Mechanisms of early functional reorganization post-lesion involve changes in the strength of synaptic coupling as measured in long-term potentiation (LTP). Since these changes in LTP may depend on the intraneuronal calcium concentration ([Ca2+]I), the present study analyzed the strength of synaptic LTP combined with measurements of the stimulus-induced peak calcium influx in slices from rat visual cortex in vitro. Slices were analyzed 1-7 days post-lesion by use of electrophysiological and calcium fluorescence imaging techniques. A theta-burst stimulus (TBS) was electrically applied to cortical layer IV, while changes in extracellular field potentials (FPs) and in the corresponding peak calcium influx were recorded in layers II/III. Both the strength of LTP and of the FP mediated peak calcium influx were significantly enhanced 1-6 days post-lesion at a distance of 4 mm from the lesion border. Pharmacological experiments revealed that the expression of LTP was dependent on the activation of NMDA receptors. The area of increased stimulus-evoked peak calcium influx correlated with the enhanced LTP, suggesting that changes in [Ca2+]I mediate the strength of long-term synaptic plasticity following a cortical lesion. This mechanism may support synaptic reorganization in the surround of the deafferented region in rat visual cortex.

Increased synaptic plasticity in the surround of visual cortex lesions in rats

Lesion-induced functional loss is reduced when new synaptic connections are established in the surround of a cortical lesion. For this, long-term synaptic plasticity can play a key role. We studied long-term potentiation (LTP) and long-term depression (LTD) in slices of rat visual cortex with small cortical lesions. Surprisingly, the normal balance between LTP and LTD was significantly altered in the first week following cortical injury. Theta-burst induced LTP was increased, whereas LTD evoked by low frequency stimulation was not affected. The increased potentiation of subcortical inputs after cortical lesions opens a window for facilitated early functional reorganization by repetitive visual training.