OBJECTIVE: To purify and study Schwann cells cytoplasmic neurotrophic protein. METHODS: The dissociated SC taken from 300 newborn rats sciatic nerves were cultured, collected, ultrasonicated and ultraspeed centrifuged. The supernates were ultrafiltrated and concentrated by using ultrafiltration units with PM10, PM30, PM50 ultrafiltration membranes. The ultrafiltrated-concentrated solution with the protein molecular weight 10-30 ku, 30-50 ku and gt; 50 ku were collected respectively. The dissociated spinal cord motoneurons of 14 days embryonic rats were cultured with serum-free conditional medium and the additional SC cytoplasmic proteins were added into the medium. The results showed that the 10-30 ku and gt; 50 ku SC cytoplasmic proteins were able to maintain the survival of motoneurons for 24 hours. Then the 26 ku and 58 ku proteins were further extracted and purified from SC cytoplasm by high pressure liquid chromatography, and their neurobiological activities were studied. RESULTS: The 26 ku and 58 ku Schwann cell’s cytoplasmic proteins were able to maintain the survival of motoneurons cultured in the serum-free medium for 48 hours. The highest biological activity concentration is 20 ng per well. CONCLUSION: Schwann cells cytoplasm contains motoneuron neurotrophic proteins with molecular weight 26 ku and 58 ku.
OBJECTIVE To study the protective effects of Schwann cell derived neurotrophic factor (SDNF) on motoneurons of spinal anterior horn from spinal root avulsion induced cell death. METHODS Twenty SD rats were made the animal model of C6.7 spinal root avulsion induced motoneuron degeneration, and SDNF was applied at the lesion site of spinal cord once a week. After three weeks, the C6.7 spinal region was dissected out for motoneuron count, morphological analysis and nitric oxide synthase (NOS) enzyme histochemistry. RESULTS 68.6% motoneurons of spinal anterior horn death were occurred after 3 weeks following surgery, the size of survivors was significantly atrophy and NOS positive neurons increased. However, in animals which received SDNF treatment, the death of motoneurons was significantly decreased, the atrophy of surviving motoneurons was prevented, and expression of NOS was inhibited. CONCLUSION SDNF can prevent the death of motoneurons following spinal root avulsion. Nitric oxide may play a role in these injury induced motoneuron death.