PDF
Abstract
A persistent infection model was established after human hepatoma cells infected by Japanese encephalitis viruses were subcultured for several times. Viral titers of mutant viruses in persistently infected cells were examined by plaque methods using BHK cells. Nucleotides of the E coding region of two wild and two mutant viruses were amplified by RT-PCR. PCR products were sequenced by ABI-PRSM™310 sequencing system. Compared to JaGAr-01 wild strains, four amino acids were replaced (E61Tyr→Asp, E219His→Tyr, E384Val→Glu, E418Pro→Ala) in the E sequence of JaGAr-01 persistently-infected mutant strains. Eleven amino acid replacement (E51Arg→Ser, E61Tyr→Asp, E83Lys→Glu, E123Ser→Arg, E209Arg→Lys, E227Pro→Ser, E276Asp→Ser, E290Arg→Lys, E387Lys→Arg, E418Leu→Pro, E454Arg→Gly) was also noted when we compared the E sequence between persistently infected Nakayama and its wild strains. A lot of similarities of amino acid sequence between mutant strains JaGAr-01 and Nakayama were also noted. It was concluded that geno-variation existed in E region of mutant viruses and the mutant protein encoded by E region, especially the mutation of E61 (Tyr→Asp) may contribute to the maintenance of the persistent infection of Japanese encephalitis virus.
Keywords
Japanese encephalitis virus
/
persistent infection
/
E sequence analysis
/
geno-variation
Cite this article
Download citation ▾
Qi Li, Keshu Xu, Huafeng Wang, Xia Zhou.
E sequence analysis of persistently infected mutant Japanese encephalitis virus strains.
Current Medical Science, 2006, 26(4): 408-410 DOI:10.1007/s11596-006-0407-9
| [1] |
PavioN., LaiM. M. C.. The hepatitis C virus persistence: how to evade the immune system?. J Biosci, 2003, 28: 287-304
|
| [2] |
ShyuW. R., WangY. C., ChinC.. Assessment of neutralizing antibodies elicited by a vaccine (Nakayama) strain of Japanese encephalitis virus in Taiwan. Epidemiol Infect, 1997, 119: 79-83
|
| [3] |
TakegamiT., SaharaM., HottaS.. A sensitive method for detection of flavivirus envelope proteins and virus titration using a monospecific antiserum against Japanese encephalitis virus envelope protein. J Kanazawa Med Univ, 1990, 15: 73-79
|
| [4] |
SambrookJ., FritschE. F., ManiatisT.. Molecular Cloning, 1989Ind ed.New York, Cold Spring Habor Laboratory Press: 345-348
|
| [5] |
ReyF. A., HeizF. X., MandleC., et al.. The envelope glyco-protein from Tick-Borne Encephalitis virus at 2 A resolution. Nature, 1995, 375: 291
|
| [6] |
Feng G H, Zhang L, Wang Y M et al. Characterization and NS3 sequence analysis of mutant strains during persistent infection of KN73 cells with Japanese encephalitis virus. Chin J Microbiol Immunol (Chinese), 2000(5):431–433
|
| [7] |
TakadaK., MasakiH., KonishiE., et al.. Definition of an epitope on Japanese encephalitis virus (JEV) envelope protein recognized by JEV-specific murine CD8+ cytotoxic T lymphocytes. Arch Virol, 2000, 145: 523-534
|
| [8] |
KolaskarA. S., Kulkarni-KaleU.. Prediction of three-dimensional structure and mapping of conformational epitopes of envelope glycoprotein of Japanese encephalitis virus. Virology, 1999, 261: 31-42
|
