Characterization of Schwann cell role in the motor neuron neurodegeneration process in amyotrophic lateral sclerosis in the transgenic animal model and in the peripheral nerve of patients: in vitro study

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease characterized by the selective loss of upper and lower motor neurons (MN). Recently, central glia (astrocytes, microglias and olygodendrocytes) were toxic to the MN, but the molecular aspects have not fully described. In relation to the peripheral glia, electrophysiological changes in the sciatic nerve of ALS animal model in the presymptomatic stage have been reported by our group and early denervation findings in both animal models and patients suggests the participation of Schwann cells (SC) in the retrograde neuronal death of ALS , theory known as dying back. In this context, the SC proved to be able to induce axonal retraction and denervation of the neuromuscular junctions, early events in the disease, possibly occurring in the pre-symptomatic phase. The aim of this thesis was to investigate the influence of SC of pre-symptomatic experimental model and from patient with recent evolution of ALS sporadic form, in the survival and axonal length of MN in vitro and understand the molecular nature of the phenomenon. Highly purified SC cultures were obtained from the sciatic nerve of the animal model and from ALS patient\'s peripheral nerve. MN from the newborn mouse spinal cord were co-cultured with SC and the neurodegeneration was assessed by the presence of the marker Fluoro-Jade C (FJC). MN were also treated with conditioned medium from cultures of SC of the animal model or ALS patients. MN had their neuronal length measured and neuronal degeneration was identified by the presence of the FJC. Several neurotrophic factors were measured in conditioned medium of mice and ALS patient\'s SC cultures by ELISA. The chain reaction quantitative polymerase (qPCR) was performed to detect changes in the SC and peripheral nerve that could be related with dysfunction in the functional unit SC/MN. The MN co-cultured with ALS SC showed a greater number of neurodegenerative profiles compared with MN cocultured with control SC. After treatment with ALS SC conditioned medium, MN showed a reduction in the neuronal length and increased number of cells in neurodegeneration compared with the control group. Lower levels of neurotrophic factors were found in the conditioned medium of ALS SC cultures. Changes in the gene expression of SC and peripheral nerve showed dysfunctions in SC/MN unit, which may be contributing to the neurodegenerative process seen in ALS. In conclusion, the failure of neuroprotection by ALS SC is an important mechanism implicated in the MN cell death, with great therapeutic potential (AU)