John H. Hughes

Internalization and Dissemination of Human Norovirus and Animal Caliciviruses in Hydroponically Grown Romaine Lettuce

ABSTRACT Fresh produce is a major vehicle for the transmission of human norovirus (NoV) because it is easily contaminated during both pre- and postharvest stages. However, the ecology of human NoV in fresh produce is poorly understood. In this study, we determined whether human NoV and its surrogates can be internalized via roots and disseminated to edible portions of the plant. The roots of romaine lettuce growing in hydroponic feed water were inoculated with 1 × 106 RNA copies/ml of a human NoV genogroup II genotype 4 (GII.4) strain or 1 × 106 to 2 × 106 PFU/ml of animal caliciviruses (Tulane virus [TV] and murine norovirus [MNV-1]), and plants were allowed to grow for 2 weeks. Leaves, shoots, and roots were homogenized, and viral titers and/or RNA copies were determined by plaque assay and/or real-time reverse transcription (RT)-PCR. For human NoV, high levels of viral-genome RNA (105 to 106 RNA copies/g) were detected in leaves, shoots, and roots at day 1 postinoculation and remained stable over the 14-day study period. For MNV-1 and TV, relatively low levels of infectious virus particles (101 to 103 PFU/g) were detected in leaves and shoots at days 1 and 2 postinoculation, but virus reached a peak titer (105 to 106 PFU/g) at day 3 or 7 postinoculation. In addition, human NoV had a rate of internalization comparable with that of TV as determined by real-time RT-PCR, whereas TV was more efficiently internalized than MNV-1 as determined by plaque assay. Taken together, these results demonstrated that human NoV and animal caliciviruses became internalized via roots and efficiently disseminated to the shoots and leaves of the lettuce.

Failure of propagation of human norovirus in intestinal epithelial cells with microvilli grown in three-dimensional cultures.

Human noroviruses (HuNoVs) are a leading cause of acute gastroenteritis. Establishment of a cell culture system for in vitro HuNoV growth remains challenging. Replication of HuNoVs in human intestinal cell lines (INT-407 and Caco-2) that differentiate to produce microvilli in rotation wall vessel (RWV) three-dimensional cultures has been reported (Straub et al. in Emerg Infect Dis 13:396–403, 2007; J Water Health 9:225–240, 2011, and Water Sci Technol 67:863–868, 2013). We used a similar RWV system, intestinal cell lines, and the same (Genogroup [G] I.1) plus additional (GII.4 and GII.12) HuNoV strains to test the system’s reproducibility and to expand the earlier findings. Apical microvilli were observed on the surface of both cell lines by light and electron microscopy. However, none of the cell types tested resulted in productive viral replication of any of the HuNoV strains, as confirmed by plateau or declining viral RNA titers in the supernatants and cell lysates of HuNoV-infected cells, determined by real-time reverse transcription PCR. These trends were the same when culture supplements were added that have been reported to be effective for replication of other fastidious enteric viruses in vitro. Additionally, by confocal microscopy and orthoslice analysis, viral capsid proteins were mainly observed above the actin filament signals, which suggested that the majority of viral antigens were on the cell surface. We conclude that even intestinal cells displaying microvilli were not sufficient to support HuNoV replication under the conditions tested.

India ink staining of proteins on nylon and hydrophobic membranes

India ink was found to be an acceptable stain for proteins blotted or dotted onto positively charged nylon or hydrophobic membranes. The hydrophobic membrane, Immobilon, was an outstanding matrix for binding proteins and displayed low levels of background staining. The least amount of protein detected by india ink staining was between 1.0 and 10 ng. India ink staining of proteins on nylon membranes is an easy, inexpensive, and quick method for the unequivocal detection of both standards and unknowns in the same blot. However, inks, ink concentrations, fixing conditions, staining times, pH, washing conditions, and membrane lots all need to be controlled to achieve maximum sensitivity for protein detection following india ink staining.

Acid Lability of Rhinovirus Type 14: Effect of pH, Time, and Temperature

Summary The kinetics of acid inactivation of human rhinovirus type 14 are affected by pH and temperature of incubation. At pH 3.0, inactivation was complete within 10 sec with total loss of infectivity. At pH 5.0, inactivation reached a maximum by 20 min and yielded a persistent fraction of infectious virus. This surviving fraction was eliminated when the pH was lowered to 3.0. At 0° no loss of infectivity was observed after 5 min of incubation at pH 5.0, while at room temperature 99% of the infectivity was lost. The characteristics of rhinovirus inactivation at low pH appears to be different from all other picornaviruses. This investigation was supported by Research Contract 69-2062 from the Infectious Disease Branch of the National Institutes of Health, and by Public Health Service General Research Support Grant RR-05504 from the Childrens Hospital Research Foundation, Columbus, Ohio 43205. The authors would like to thank Miss Helen Rehn for typing the manuscript.

Epidemiology, prevention, and control of the number one foodborne illness: human norovirus.

Human norovirus (NoV) is the number one cause of foodborne illness. Despite tremendous research efforts, human NoV is still poorly understood and understudied. There is no effective measure to eliminate this virus from food and the environment. Future research efforts should focus on developing: (1) an efficient cell culture system and a robust animal model, (2) rapid and sensitive detection methods, (3) novel sanitizers and control interventions, and (4) vaccines and antiviral drugs. Furthermore, there is an urgent need to build multidisciplinary and multi-institutional teams to combat this important biodefense agent.

Inhibition of rotavirus in vitro transcription by optimal concentrations of monoclonal antibodies specific for rotavirus VP6

Three monoclonal antibodies (MAbs) obtained from inoculation of mice with either a serotype 1 human rotavirus or rotavirus SA11 (serotype 3) inhibited the in vitro transcription of rotavirus SA11. Two of the MAbs exhibited a biphasic inhibitory response. Removal of antibody from MAb preparations by adsorption with Sepharose-Protein G reduced the inhibitory activity completely for all three MAb preparations. Analysis by radioimmunoprecipitation and Western blotting indicated that all three MAbs reacted with VP6. All MAbs also reacted with four group A rotavirus serotypes by ELISA, but did not cross-react with reovirus type 1, poliovirus type 2 or MA-104 cell lysates. Transcription of four rotavirus serotypes as well as epizootic diarrhoea of infant mice rotavirus was inhibited when tested with two of the MAbs. Transcription of both purified single-shelled virus and purified heat-activated double-shelled SA11 rotavirus was inhibited by purified MAb. Our results indicate that these MAbs can be used effectively to study the events associated with rotavirus transcription.

Rhinoviruses: Kinetics of ultraviolet inactivation and effects of UV and heat on immunogenicity

SummaryThe kinetics of ultraviolet inactivation for two human rhinoviruses and poliovirus were compared. No major differences in the rates of ultraviolet inactivation were detectable. All viral preparations inactivated by ultraviolet irradiation induced neutralizing antibody in guinea pigs. In contrast, when guinea pigs were immunized with a heat inactivated rhinovirus preparation, little or no neutralizing antibody was elicited. Immune electron microscopy of the heated rhinovirus preparations revealed the presence of particles resembling empty capsids. These results suggest that rhinoviruses and enteroviruses are affected in a similar manner when subjected to ultraviolet or heat inactivation.

SIMULATED MICROGRAVITY IMPAIRS RESPIRATORY BURST ACTIVITY IN HUMAN PROMYELOCYTIC CELLS

SummaryThe concept of microgravity (free-fall) influencing cellular functions in nonadherent cells has not been a part of mainstream scientific thought. Utilizing rotating wall vessels (RWVs) to generate simulated microgravity conditions, we found that respiratory burst activity was significantly altered in nonadherent promyelocytic (HL-60) cells. Specifically, HL-60 cells in simulated microgravity for 6, 19, 42, 47, and 49 d had 3.8-fold fewer cells that were able to participate in respiratory burst activity than cells from 1×g cultures (P=0.0011, N=5). The quantity of respiratory burst products from the cells in simulated microgravity was also significantly reduced. The fold increase over controls in mean fluorescence intensities for oxidative products from cells in microgravity was 1.1±0.1 versus 1.8±0.3 for cells at 1 ×g (P=0.013, N=4). Furthermore, the kinetic response for phorbol ester-stimulated burst activity was affected by simulated microgravity. These results demonstrate that simulated microgravity alters an innate cellular function (burst activity). If respiratory burst activity is impaired by true microgravity, then recovery from infections during spaceflight could be delayed. Finally, RWVs provide an excellent model for investigating the mechanisms associated with microgravity-induced changes in nonadherent cells.

Attachment and localization of human norovirus and animal caliciviruses in fresh produce.

Fresh produce is a high risk food for human norovirus (NoV) contamination. To help control this pathogen in fresh produce, a better understanding of the interaction of human NoV and fresh produce needs to be established. In this study the attachment of human NoV and animal caliciviruses (murine norovirus, MNV-1; Tulane virus, TV) to fresh produce was evaluated, using both visualization and viral enumeration techniques. It was found that a human NoV GII.4 strain attached efficiently to the Romaine lettuce leaves and roots and green onion shoots, and that washing with PBS or 200 ppm of chlorine removed less than 0.4 log of viral RNA copies from the tissues. In contrast, TV and MNV-1 bound more efficiently to Romaine lettuce leaves than to the roots, and simple washing removed less than 1 log of viruses from the lettuce leaves and 1-4 log PFU of viruses from roots. Subsequently, the location of virus particles in fresh produce was visualized using a fluorescence-based Quantum Dots (Q-Dots) assay and confocal microscopy. It was found that human NoV virus-like particles (VLPs), TV, and MNV-1 associated with the surface of Romaine lettuce and were found aggregating in and around the stomata. In green onions, human NoV VLPs were found between the cells of the epidermis and cell walls of both the shoots and roots. However, TV and MNV-1 were found to be covering the surface of the epidermal cells in both the shoots and roots of green onions. Collectively, these results demonstrate that (i) washing with 200 ppm chlorine is ineffective in removing human NoV from fresh produce; and (ii) different viruses vary in their localization patterns to different varieties of fresh produce.

Epstein-barr virus latently infected cells are selectively deleted in simulated-microgravity cultures

SummaryRotating-wall vessels (RWVs) allow for the cultivation of cells in simulated microgravity. Previously, we showed that the cultivation of lymphoblastoid cells in simulated microgravity results in the suppression of Epstein—Barr virus (EBV) reactivation. To determine if the suppression generated by simulated microgravity could be reversed by changing to static culture conditions, cells were cultured in an RWV for 5 d, and then switched to static conditions. Following the switch to static conditions, viral reactivation remained suppressed (significantly lower) relative to static control cultures over a 4-d period. Additionally, experiments were conducted to determine if chemical treatment could induce viral reactivation in cells from simulated-microgravity cultures. Cells were cultured in static flask cultures and in simulated microgravity in RWVs for 4–7 d. The cells were then transferred to 50-cm3 tubes, and treated with 3 mM n-butyrate for 48 h, or 18 ng/ml of phorbol ester, viz., 12-0-tetradecanoylphorbol-13 acetate (TPA) for either 2 or 48 h, under static conditions. Although EBV was inducible, the cells from simulated-microgravity cultures treated withn-butyrate displayed significantly lower levels of viral-antigen expression compared with the treated cells from static cultures. Also, incubation with TPA for 2–3 h, but not for 48 h, reactivated EBV in cells from RWV cultures. In contrast, EBV was inducible in cells from static cultures treated for either 2–3 or 48 h with TPA. TPA reactivation of EBV following a 2–3-h period of treatment indicates that the protein kinase C signal-transduction pathway is not impaired in lymphoblastoid cells cultured in simulated microgravity. However, the exposure of B-lymphoblastoid cells from simulated-microgravity cultures to TPA for more than 3–4 h triggered a lytic event (apoptosis or necrosis), which prevented replication of the virus. Thus, EBV-infected cells in simulated microgravity were negatively selected in the absence of any cytotoxic cells.