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TMV在不同水体与温度条件下的灭活动力学 被引量:2

Inactivation Dynamics of TMV under Different Water Bodies and Temperatures
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摘要 了解植物病毒在不同水体与温度条件下的灭活规律具有重要的理论与实际意义。本文以典型植物病毒烟草花叶病毒(TMV)为模型,比较了其在不同温度条件下,在闽江水、自来水、生活污水、微孔滤膜过滤除菌污水及超纯水中的灭活动力学。结果显示,温度是导致TMV灭活的重要因素,水温升高,病毒灭活速率加快;此外,某些水质因子也影响TMV的灭活效率,其中可溶性盐的存在及其含量对TMV的灭活会因所处的环境不同而异;某些微生物或代谢产物对植物病毒TMV具有灭活作用,而能生化降解的有机质加速TMV灭活可能是通过促进水体中的微生物增殖而起作用。 It is very important to understand the laws of Tobacco mosaic virus(TMV) inactivation under different water bodies and temperatures. Choosing the typical plant virus TMV as a model virus, the inactivation dynamics of it in Min River water, tap water, super-pure water, life sewage and sterile sewage under different temperatures were studied in this paper. The results showed that the temperature was a very important factor to influence the survival of TMV. The higher temperature of the water body, the faster the inactivation rate of TMV. Besides the environmental temperature, some water quality factors also influence the inactivation rate of TMV. The influences of the dissolved salts on the inactivation of TMV were different from the various environmental conditions. Some microbes or their metabolites were harmful to the survival of TMV. The biodegradable organic substances lead to TMV inactivation may be throught to promote the bacteria multiplying.
作者 郑耀通 林奇英 谢联辉
机构地区 福建农林大学资源与环境学院 福建农林大学植物病毒研究所
出处 《中国病毒学》 CAS CSCD 2004年第4期385-388,共4页 Virologica Sinica
基金 福建省科技计划项目资助(R-98-17)
关键词 烟草花叶病毒 TMV 水体 温度 灭活 动力学 Tobacco mosaic virus (TMV) Inactivation Dynamics Water body
分类号 S432.4 [农业科学—植物病理学]
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参考文献13

  • 1郑耀通,林奇英,谢联辉.水体环境的植物病毒及其生态效应[J].中国病毒学,2000,15(1):1-7. 被引量:10
  • 2Plese N, Juretic N, Mamula D. Plant viruses in soil and water of forest ecosystems in Croatia[j]. Phyton, 1996, 36(1): 135-143
  • 3Yahya M T, Cluff C B, Gerba C P. Virus removal by slow filtration and nanofiltration[J]. Wat Sci Tech, 1993, 27(2): 409-412.
  • 4Yate M V, Gerba C P, Kelly L M.Virus persistence in groundwater[J]. Appl Environ Microbiol, 1985, 49(3): 778-781.
  • 5Yarwood G E. Release and preservation of virus by boots[J]. Phytopathology, 1960, 50(1):111-114
  • 6Smith P R, Campbeu R N. Isolation of plant viruses from surface water[J]. Phytopathology, 1969, 59(15): 1678-687.
  • 7Kerler G, Kleinthempel H,Kegler H. Investigation on the soil transmissibility of tomato bushy stunt virus[J]. Arch Phytopathol Pflanzenschutz, 1980, 16(2):73-76.
  • 8Lanter J M, Goode M J, Mcguire J M. Persistence of tomato mosaic virus in tomato debris and soil under field conditions[J]. Plant Dis,1982, 66(7): 552-555.
  • 9Kleinhempel H, Gruber G. Transmission of tomato bushy stunt virus without vectors[J]. Acta Phytopathol Acad Sci Hung, 1982, 15(3):107-111.
  • 10Kegler G, Kerler H. On vectorless transmission of plant pathogenic viruses[J]. Arch Phytopathol Pflanzenschutz, 1981, 17(5):307-323.

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中国病毒学
2004年 第4期

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