Proteomic Analysis of Mycoplasma gallisepticum Vaccine Strain F
作者: S.D. Collier , S.L. Branton , J.D. Evans , S.A. Leigh , X.F. Wan
关键词: Membrane protein 、 Chemistry 、 Protein biosynthesis 、 Mycoplasma gallisepticum vaccine 、 Mycoplasma gallisepticum 、 SOSUI 、 Proteome 、 Whole cell lysate 、 Cytosol 、 Biochemistry
摘要: The persistence and displacement abilities of the Mycoplasma gallisepticum vaccine strain F (F-strain) are well documented. Understanding mechanism(s) colonization F-strain will aid in current intervention strategies to diagnose control MG infections poultry. In present study, phase partition liquid chromatography along with electrospray mass spectrometry were used evaluate proteome F-strain. A total 586, 478 339 proteins recognized from whole cell lysate (total protein), aqueous (cytosolic) detergent phases (membrane), respectively. identified database searches then grouped into three categories: (1) membrane found (TM); (2) cytosolic (TC) (3) derived (TMC). There a 93 (33 as putative predicted by SOSUI), 207(13) 79(6) TM, TC TMC, distributed among John Craig Venter Institute (JCVI) categories, majority be involved protein synthesis. Investigation may identification characterization that important host colonization.
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researchgate.net 参考文章(41)
R P Hanson, D P Andrson, M L Frey, A medium for the isolation of avian mycoplasmas. American Journal of Veterinary Research. ,vol. 29, pp. 2163- 2171 ,(1968)
S. H. Kleven, M. I. Khan, R. Yamamoto, Fingerprinting of Mycoplasma gallisepticum strains isolated from multiple-age layers vaccinated with live F strain. Avian Diseases. ,vol. 34, pp. 984- 990 ,(1990) , 10.2307/1591393
I. A. Demina, M. V. Serebryakova, V. G. Ladygina, M. A. Rogova, V. G. Zgoda, D. A. Korzhenevskyi, V. M. Govorun, Proteome of the bacterium Mycoplasma gallisepticum Biochemistry. ,vol. 74, pp. 165- 174 ,(2009) , 10.1134/S0006297909020072
Tanja Davidsen, Erin Beck, Anuradha Ganapathy, Robert Montgomery, Nikhat Zafar, Qi Yang, Ramana Madupu, Phil Goetz, Kevin Galinsky, Owen White, Granger Sutton, The comprehensive microbial resource Nucleic Acids Research. ,vol. 38, pp. 123- 125 ,(2001) , 10.1093/NAR/GKP912
S. H. Kleven, H.-H. Fan, K. S. Turner, Pen Trial Studies on the Use of Live Vaccines to Displace Virulent Mycoplasma gallisepticum in Chickens Avian Diseases. ,vol. 42, pp. 300- 306 ,(1998) , 10.2307/1592480
T. Y. Abd-El-Motelib, S. H. Kleven, A comparative study of Mycoplasma gallisepticum vaccines in young chickens. Avian Diseases. ,vol. 37, pp. 981- 987 ,(1993) , 10.2307/1591903
KG WHITHEAR, E. GHIOCAS, PF MARKHAM, D. MARKS, Examination of Mycoplasma gallisepticum isolates from chickens with respiratory disease in a commercial flock vaccinated with a living M. gallisepticum vaccine. Australian Veterinary Journal. ,vol. 67, pp. 459- 460 ,(1990) , 10.1111/J.1751-0813.1990.TB03067.X
Gleb Y. Fisunov, Dmitry G. Alexeev, Nicolay A. Bazaleev, Valentina G. Ladygina, Maria A. Galyamina, Ilya G. Kondratov, Nadezhda A. Zhukova, Marina V. Serebryakova, Irina A. Demina, Vadim M. Govorun, Core proteome of the minimal cell: comparative proteomics of three mollicute species PLOS ONE. ,vol. 6, ,(2011) , 10.1371/JOURNAL.PONE.0021964
Hongjun Chen, Shengqing Yu, Xinyue Shen, Danqing Chen, Xvsheng Qiu, Cuiping Song, Chan Ding, None, The Mycoplasma gallisepticum α-enolase is cell surface-exposed and mediates adherence by binding to chicken plasminogen. Microbial Pathogenesis. ,vol. 51, pp. 285- 290 ,(2011) , 10.1016/J.MICPATH.2011.03.012
M. D. Glew, Glenn F. Browning, Philip F. Markham, Ian D. Walker, pMGA phenotypic variation in Mycoplasma gallisepticum occurs in vivo and is mediated by trinucleotide repeat length variation. Infection and Immunity. ,vol. 68, pp. 6027- 6033 ,(2000) , 10.1128/IAI.68.10.6027-6033.2000