Adsorption of Reovirus by Minerals and Soils

Overview

Journal Appl Environ Microbiol

Specialties Environmental Health
Microbiology

Date 1982 Oct 1

PMID 7149717

Citations 10

Authors

R S Moore

D H Taylor

M M Reddy

L S Sturman

Affiliations

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Abstract

Adsorption of [35S]methionine-labeled reovirus by 30 dry soils, minerals, and finely ground rocks suspended in synthetic freshwater at pH 7 was investigated to determine the conditions necessary for optimum virus removal during land application of wastewaters. All of the minerals and soils studied were excellent adsorbents of reovirus, with greater than 99% of the virus adsorbed after 1 h at 4 degrees C. Thereafter, virus remaining in suspension was significantly inactivated, and within 24 h a three to five log10 reduction in titer occurred. The presence of divalent cations, i.e., Ca2+ and Mg2+, in synthetic freshwater enhanced removal, whereas soluble organic matter decreased the amount of virus adsorbed in secondary effluent. The amount of virus adsorbed by these substrates was inversely correlated with the amount of organic matter, capacity to adsorb cationic polyelectrolyte, and electrophoretic mobility. Adsorption increased with increasing available surface area, as suspended infectivity was reduced further by the more finely divided substrates. However, the organic content of the soils reduced the level of infectious virus adsorbed below that expected from surface area measurements alone. The inverse correlation between virus adsorption and substrate capacity for cationic polyelectrolyte indicates that the adsorption of infectious reovirus particles is predominately a charged colloidal particle-charged surface interaction. Thus, adsorption of polyelectrolyte may be useful in predicting the fate of viruses during land application of sewage effluents and sludges.

Citing Articles

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Host Membranes as Drivers of Virus Evolution.

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A Roadmap for Building Waterborne Virus Traps.

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Optimization of viral resuspension methods for carbon-rich soils along a permafrost thaw gradient.

Trubl G, Solonenko N, Chittick L, Solonenko S, Rich V, Sullivan M PeerJ. 2016; 4:e1999.

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Virus adsorption to mineral surfaces is reduced by microbial overgrowth and organic coatings.

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PMID: 24221237 DOI: 10.1007/BF02015106.

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