Interneurons containing somatostatin are affected by learning-induced cortical plasticity.

The maintenance of neural circuit stability is a dynamic process that requires the plasticity of many cellular and synaptic components. By changing the excitatory/inhibitory balance, inhibitory GABAergic plasticity can regulate excitability, and contribute to neural circuit function and refinement in learning and memory. Increased inhibitory GABAergic neurotransmission has been shown in brain structures involved in the learning process. Previously, we showed that classical conditioning in which tactile stimulation of one row of vibrissae (conditioned stimulus, CS) was paired with a tail shock (unconditioned stimulus, UCS) in adult mice results in the increased density of GABAergic interneurons and increased expression of glutamic acid decarboxylase (GAD)-67 in barrels of the "trained" row cortical representation. In inhibitory neurons of the rat cortex GAD co-localizes with several proteins and peptides. We found previously that the density of the parvalbumin (GAD+/Prv+)-containing subpopulation is not changed after conditioning. In the present study, we examined GABAergic somatostatin (Som)-, calbindin (CB)- and calretinin (CR)-positive interneurons in the cortical representation of "trained" vibrissae after training. Cells showing double immunostaining for GAD/Som, GAD/CR and GAD/CB were counted in the barrels representing vibrissae activated during the training and in control, untouched rows. We found a substantial increase of GAD/Som-containing cells in the trained row representation. No changes in the density of GAD/CR or GAD/CB neurons were observed. These results suggest that Som-containing interneurons are involved in learning-induced changes in the inhibitory cortical network.

Correlated activation of the thalamocortical network in a simple learning paradigm.

The thalamocortical loop is a key player in sensory processing. We examined the functional interactions among its elements, expressed as cross-correlations between metabolic activity of the barrel cortex, somatosensory thalamic nuclei and posterior parietal cortex, in classical conditioning. In the training stimulation of vibrissae in mice was paired with a tail shock. [14C]-2-Deoxyglucose brain mapping was performed during the first and the final sessions of conditioning (conditioned stimulus+unconditioned stimulus; CS+UCS), in groups that received only the stimulation of vibrissae (conditioned stimulus; CS-only) and in nonstimulated controls (NS). In the CS-only group, the CS evoked the correlated activity of the examined structures during the first session, but in the third session these structures did not act in a correlated manner. Conversely, in the CS+UCS condition correlations among the thalamocortical loop structures activities became stronger during the course of the training. Particularly, the posterior parietal cortex, which controls voluntary deployment of attention, together with the barrel cortex becomes involved in the network of structures with the correlated activity. The results suggest a predominant role for bottom-up processing in the somatosensory pathway at the beginning of conditioning followed by top-down processing. This is consistent with the idea that the thalamocortical loop plays a crucial role in attentional processes.

Matrix metalloproteinase inhibition counteracts impairment of cortical experience-dependent plasticity after photothrombotic stroke.

Matrix metalloproteinases (MMPs) are fine modulators of brain plasticity and pathophysiology. The inhibition of MMPs shortly after ischaemic stroke reduces the infarct size and has beneficial effects on post-stroke behavioural recovery. Our previous studies have shown that photothrombotic cortical stroke disrupts use-dependent plasticity in the neighbouring cortex. The aim of the present study was to check whether the inhibition of MMPs after photothrombosis rescued the plastic capacity of the barrel cortex. To induce plasticity in adult mice, a unilateral deprivation of all vibrissae except row C was applied. The deprivation started immediately after stroke and lasted 7 days. This procedure, in control (non-stroke) animals, results in an enlargement of functional representation of the spared row, as shown with [(14)C]2-deoxyglucose uptake mapping. In mice with stroke induced by photothrombosis in the vicinity of the barrel cortex, vibrissae deprivation did not result in an enlargement of the cortical representation of the spared row C of vibrissae, which confirmed our previous results. However, when mice were injected with the broad-spectrum inhibitor of MMPs FN-439 (10 mg/kg, i.v.) immediately before a stroke, an enlargement of the representation of the spared row similar to the enlargement found in sham mice was observed. These results indicate the involvement of MMPs in the impairment of use-dependent plasticity in the vicinity of an ischaemic lesion.

Mice can learn roughness discrimination with vibrissae in a jump stand apparatus.

An adaptation of roughness discrimination task successfully used on rats was performed on mice. It was found that mice can master discrimination of rough surfaces using only mystacial vibrissae. This task can be used for studying sensory abilities of genetically modified mice as well as dynamics and pharmacology of complex sensory learning.