Interferon of impact gamma in the of synaptic plasticity after sciatic nerve lesion

In the spinal cord, the establishment of synapses is probably coordinated by the neurons. However, the glial cells and surrounding microenvironment formed between neurons/glia play an important role in modulating neural excitability, influencing the transmission and synaptic plasticity. In situations of injury or inflammation, there is an increase in glial reactivity and changes in functional status of neurons, with a consequent cascade of events aimed at restoration of homeostasis. In this regard, IFN? is involved in regulating the expression of MHC I, which has recently been shown to play an important role in the synaptic plasticity processes following axotomy. Also, there is evidence that IFN? absence on spinal cord neurons after injury. The aim of this study was to investigate the phenomena of synaptic plasticity and glial reactivity in mice mutant for IFN? in order to analyze the dynamics of spinal synapses after injury of the sciatic nerve in animals unable to regulate the expression of MHC I due the absence of IFN?. In this sense, mutant mice for IFN? and wild type C57BL/6J were subjected to unilateral transection or crushing of the sciatic nerve (5animals/group/experiment), and the specimens were processed for immunohistochemistry, Western blotting, light and transmission electron microscopy (TEM). In addition, the motor evaluation of the mice was investigated by the sciatic functional index. Spinal cord sections from non-lesioned animals were also used to investigate neuronal survival and the presence of apoptosis with TUNEL and caspase 3 immunostaining. Astrocytes from mutant and wild type newborn mice were also investigated in primary cell culture. The absence of IFN? in the mutant animals produced reduced expression of MHC I after one week from injury. Motoneurons in the lower lumbar ventral horn exhibited a smaller soma size and increased number of degenerated cells?when compared to wild type mice. Sciatic nerve axotomy did not further aggravate the neuronal loss in the mutant mice. Apoptotic death is suggested on TUNEL and caspase 3 positive immunostaining. The electron microscopy showed a smaller retraction of pre-synaptic terminals apposing to motoneurons in mutant mice one week after lesion. The absence of IFN? did not impair motor recovery of the mutant animals. In culture, astrocytes from mutant animals showed a delay in the rate of proliferation probably due to the absence of IFN?. Altogether, these results suggest that IFN? may be neuroprotective and its absence results in neuronal death, which is not further increased by peripheral axotomy. (AU)