THE DEVELOPMENT OF VACCINIA VIRUS IN EARLE'S L STRAIN CELLS AS EXAMINED BY ELECTRON MICROSCOPY

doi:10.1083/jcb.10.4.475

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ARTICLE

THE DEVELOPMENT OF VACCINIA VIRUS IN EARLE'S L STRAIN CELLS AS EXAMINED BY ELECTRON MICROSCOPY

S. Dales Ph.D.¹ and L. Siminovitch Ph.D.¹

¹ From the Ontario Cancer Institute and Department of Medical Biophysics, University of Toronto, Canada.

Dr. Dales' present address is the Department of Cytology, The Rockefeller Institute

A favorable system which is amenable to frequent and reproduciblesampling, consisting of suspension cultures of strain L cellsand vaccinia virus, was employed to study the animal virus-mammalianhost cell relationship. The three principal aspects investigatedconcerned the adsorption and penetration of vaccinia into thehost, the relationship between the sequence of virus developmentand the production of infectious particles, and the changesin the fine structure of the host cells. Experiments in whicha very high multiplicity of infection was used revealed thatvaccinia is phagocytized by L cells in less than 1 hour afterbeing added to the culture, without any apparent loss of itsouter limiting membranes. Regions of dense fibrous material,thought to be foci of presumptive virus multiplication, appearin the cytoplasm 2 hours after infection. A correlation betweenelectron microscope studies and formation of infectious particlesshows that although immature forms of the virus appear 4 hoursafter infection, infectious particles are produced 6 hours afterinfection of the culture, at the time when mature forms of vacciniaappear for the first time in thinly sectioned cells. Spreadof the infection is gradual until eventually, after 24 hours,virus is being elaborated throughout the cytoplasm. Additionof vaccinia to monolayer cultures induced fusion of L cellsand rapid formation of multinucleate giant forms. In both suspensionand stationary cultures infected cells elaborate a variety ofmembranous structures not present in normal L cells. These takethe form of tube-like lamellar and vesicular formations, orappear as complex reticular networks or as multi-laminar membraneswithin degenerating mitochondria.

Submitted on April 14, 1961

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