Pockets in proteins have been known to be very important for the life process. There have been several studies in the past to automatically extract the pockets from the structure information of known proteins. However...Pockets in proteins have been known to be very important for the life process. There have been several studies in the past to automatically extract the pockets from the structure information of known proteins. However, it is difficult to find a study comparing the precision of the extracted pockets from known pockets on the protein. In this paper, we propose an algorithm for extracting pockets from structure data of proteins and analyze the quality of the algorithm by comparing the extracted pockets with some known pockets. These results in this paper can be used to set the parameter values of the pocket extraction algorithm for getting better results.展开更多
Objective To investigate the possibility of the transfection of glial-cell line derived neurotro-phic factor (GDNF) gene into Schwann cells (SCs). Methods SCs cultures from sciatic nerves of neonatal rats were establi...Objective To investigate the possibility of the transfection of glial-cell line derived neurotro-phic factor (GDNF) gene into Schwann cells (SCs). Methods SCs cultures from sciatic nerves of neonatal rats were established. A recombinant retrovirus vector containing GDNF gene was constructed and transferred into SCs. Expression levels of GDNF mRNA and protein were respectively identified with reverse transcriptase-polymerase chain reaction (RT-PCR) and immunocytochemistry. Determination of GDNF synthesis rates from Retro. pLNCX2-GDNF-transduced SCs (GDNF-SCs) in vitro by enzyme-linked immunoassay sensitive assay (ELISA). Biololgical activity of conditioned medium from GENF-SCs was analysed by co-culture with rat motoneurons. Results Transfection of GDNF gene into SCs lead to significantly enhanced expression of GDNF mRNA and protein. The rate of GDNF secreted by GDNF-SCs was also enhanced(5. 1-fold) ,and more motoneurons survived co-cultured with conditioned medium of GNDF-SCs than with that of normal SCs. Conclusion GNDF gene transfection may be a better way to graft SCs promoting regeneration and repairing demyelination in PNS and CNS.展开更多
基金Project supported by Creative Research Initiative from the Ministry of Science and Technology (MOST), Korea. BHAK Jonghwa is supported by Biogreen21 Fund and MOST Funds, Korea
文摘Pockets in proteins have been known to be very important for the life process. There have been several studies in the past to automatically extract the pockets from the structure information of known proteins. However, it is difficult to find a study comparing the precision of the extracted pockets from known pockets on the protein. In this paper, we propose an algorithm for extracting pockets from structure data of proteins and analyze the quality of the algorithm by comparing the extracted pockets with some known pockets. These results in this paper can be used to set the parameter values of the pocket extraction algorithm for getting better results.
文摘Objective To investigate the possibility of the transfection of glial-cell line derived neurotro-phic factor (GDNF) gene into Schwann cells (SCs). Methods SCs cultures from sciatic nerves of neonatal rats were established. A recombinant retrovirus vector containing GDNF gene was constructed and transferred into SCs. Expression levels of GDNF mRNA and protein were respectively identified with reverse transcriptase-polymerase chain reaction (RT-PCR) and immunocytochemistry. Determination of GDNF synthesis rates from Retro. pLNCX2-GDNF-transduced SCs (GDNF-SCs) in vitro by enzyme-linked immunoassay sensitive assay (ELISA). Biololgical activity of conditioned medium from GENF-SCs was analysed by co-culture with rat motoneurons. Results Transfection of GDNF gene into SCs lead to significantly enhanced expression of GDNF mRNA and protein. The rate of GDNF secreted by GDNF-SCs was also enhanced(5. 1-fold) ,and more motoneurons survived co-cultured with conditioned medium of GNDF-SCs than with that of normal SCs. Conclusion GNDF gene transfection may be a better way to graft SCs promoting regeneration and repairing demyelination in PNS and CNS.
