Use of modified diatomaceous earth for removal and recovery of viruses in water.

Diatomaceous earth was modified by in situ precipitation of metallic hydroxides. Modification decreased the negative charge on the diatomaceous earth and increased its ability to adsorb viruses in water. Electrostatic interactions were more important than hydrophobic interactions in virus adsorption to modified diatomaceous earth. Filters containing diatomaceous earth modified by in situ precipitation of a combination of ferric chloride and aluminum chloride adsorbed greater than 80% of enteroviruses (poliovirus 1, echovirus 5, and coxsackievirus B5) and coliphage MS2 present in tap water at ambient pH (7.8 to 8.3), even after filtration of 100 liters of tap water. Viruses adsorbed to the filters could be recovered by mixing the modified diatomaceous earth with 3% beef extract plus 1 M NaCl (pH 9).

Detection of nucleic acids homologous to human immunodeficiency virus in wastewater.

Raw wastewaters were obtained from the cities of Belle Glade, Ocala and Gainesville in the state of Florida and were concentrated using several established methods for the recovery of human enteroviruses. The nucleic acids were then extracted from the wastewater concentrates, suspended in 2 x SSC with and without 2 N NaOH (for the detection of DNA and both DNA and RNA, respectively), and dot blotted onto hybridization membranes. These membranes were then hybridized with three 32P-end-labeled 18-mer oligonucleotides directed against the LTR, gag, and env regions of the human immunodeficiency virus type 1 (HIV-1). Autoradiographic analyses of these blots indicate that sequences homologous to HIV-1 genomic RNA and proviral DNA were found in Belle Glade wastewater but not in wastewater from Ocala and Gainesville. These findings may have implications in the wastewater treatment system as well as for detection of HIV-1 in clinical samples.

Development and application of new positively charged filters for recovery of bacteriophages from water.

Electronegative and electropositive filters were compared for the recovery of indigenous bacteriophages from water samples, using the VIRADEL technique. Fiber glass and diatomaceous earth filters displayed low adsorption and recovery, but an important increase of the adsorption percentage was observed when the filters were treated with cationic polymers (about 99% adsorption). A new methodology of virus elution was developed in this study, consisting of the slow passage of the eluent through the filter, thus increasing the contact time between eluent and virus adsorbed on the filters. The use of this technique allows a maximum recovery of 71.2% compared with 46.7% phage recovery obtained by the standard elution procedure. High percentages (over 83%) of phage adsorption were obtained with different filters from 1-liter aliquots of the samples, except for Virosorb 1-MDS filters (between 1.6 and 32% phage adsorption). Phage recovery by using the slow passing of the eluent depended on the filter type, with recovery ranging between 1.6% for Virosorb 1-MDS filters treated with polyethyleneimine and 103.2% for diatomaceous earth filters treated with 0.1% Nalco.

Detection and identification of poliovirus in environmental samples using nucleic acid hybridization.

A procedure was developed to effectively extract viral RNA from poliovirus tissue-culture lysates while eliminating the hybridization background associated with tissue cultures uninfected with poliovirus. Poliovirus cDNA cloned into a pUC vector was used as probe. Both the recombinant plasmids and the cDNA showed great specificity towards poliovirus. However, both probes hybridized with the single-stranded DNA coliphage phi X174. Tissue culture was found to be an effective method to increase the number of viruses found in environmental samples to a level detectable by hybridization procedures, whereas direct hybridization of RNA from unamplified and highly concentrated raw wastewater showed poor hybridization signals. The specificity and sensitivity of the hybridization procedure developed during these studies indicate that this method may be best suited for the identification rather than the detection of viruses isolated from environmental samples.

Enhancement of enterovirus infectivity in vitro by pretreating host cell monolayers with the cationic polymer polyethyleneimine.

Laboratory strains of enteroviruses, as well as viruses isolated from raw wastewater, were found to exhibit enhanced infectivity in vitro when BGM cell monolayers were pretreated with the cationic polymer polyethyleneimine (PEI). Viruses were assayed by the cytopathic effect technique and as PFU under methylcellulose and agar overlays with monolayers treated with 0 to 5.0 x 10(-3)% (wt/vol) PEI in phosphate-buffered saline supplemented with 2% fetal bovine serum. Poliovirus type 1 cytopathic effect occurred at an enhanced rate in cells treated with 5.0 x 10(-3)% PEI compared with untreated cells. PEI-treated cells were found to adsorb viruses much more effectively than untreated cells did. When the methylcellulose overlay procedure was used, rates of infectivity were enhanced as follows: poliovirus type 1, 5.5-fold; echovirus type 1, 1.2-fold; echovirus type 5, 5.2-fold; and coxsackievirus type B5, 4.9-fold. Viruses concentrated from raw wastewater showed a 3.8-fold increase in titer when quantitated by the most-probable-number method and a 3.3-fold increase when quantitated as PFU under an agar overlay.

Activation thermodynamics of virus adsorption to solids.

The kinetics of bacteriophage MS2, T2, and f2 adsorption to powdered nitrocellulose and disrupted Seitz S1 filters at pH 7 were determined as a function of temperature. Data from these studies were combined with data produced in a previous study on MS2 adsorption to clay by Stagg et al. (Appl. Environ. Microbiol. 33:385-391, 1977). These workers studied the adsorption of MS2 to bentonite clay as a function of temperature. Data from both this previous study and the current one were used to calculate the thermodynamic parameters of virus adsorption. The results show that adsorption of bacteriophages to the solids tested is a physical process (energy of activation, less than 40 kcal [168 J]/mol) rather than a chemical process (energy of activation, greater than 40 kcal/mol). The free energy of activation showed a high negative correlation (r = -0.904, r2 = 0.817) with the percentage of virus adsorption to the solids tested. The energy of activation was highly negatively correlated with the percentage of virus adsorption to nitrocellulose and clay (r = -0.913, r2 = 0.834) but poorly correlated with the percentage of virus adsorption to disrupted Seitz S1 filters (r = -0.348, r2 = 0.121). In general, under conditions in which the percentage of virus adsorption was low, the energy of activation, the free energy of activation, and the entropy of activation were high. Increasing the percentage of virus adsorbed by changing the adsorbing conditions or changing the adsorbing solid decreased the energy of activation, the free energy of activation, and the entropy of activation.

Novel approach for modifying microporous filters for virus concentration from water.

Electronegative microporous filters composed of epoxyfiberglass (Filterite) were treated with cationic polymers to enhance their virus-adsorbing properties. This novel and inexpensive approach to microporous filter modification entails soaking filters in an aqueous solution of a cationic polymer such as polyethyleneimine (PEI) for 2 h at room temperature and then allowing the filters to air dry overnight on absorbent paper towels. PEI-treated filters were evaluated for coliphage (MS2, T2, and phi X174) and enterovirus (poliovirus type 1 and coxsackievirus type B5) adsorption from buffer at pH 3.5 to 9.0 and for indigenous coliphages from unchlorinated secondary effluent at ambient pH. Adsorbed viruses were recovered with 3% beef extract (pH 9). Several other cationic polymers were used to modify epoxyfiberglass filters and were evaluated for their ability to concentrate viruses from water. Zeta potentials of disrupted filter material indicated that electronegative epoxyfiberglass filters were made more electropositive when treated with cationic polymers. In general, epoxyfiberglass filters treated with cationic polymers were found to adsorb a greater percentage of coliphages and enteroviruses than were untreated filters.

Concentration of viruses from water by using cellulose filters modified by in situ precipitation of ferric and aluminum hydroxides.

Untreated cellulose filters adsorbed only small amounts of poliovirus 1, echovirus 5, coxsackievirus B5, or bacteriophage MS2 that were added to tap water or to solutions of imidazole-glycine buffer at pH 5 to 7. Modification of filters by in situ flocculation of ferric and aluminum hydroxides greatly increased the ability of the filters to adsorb viruses. Viruses adsorbed to the modified filters could be recovered by treating the filters with 3% beef extract (pH 9.5). Greater than 60% of the enteroviruses and greater than 55% of the MS2 added to tap water or buffer could be recovered in the beef extract eluate.