Autophagy is an essential component of host immunity and used by viruses for survival. However, the autophagy signaling pathways involved in virus replication are poorly documented. Here, we observed that rabies virus (RABV) infection triggered intracellular autophagosome accumulation and results in incomplete autophagy by inhibiting autophagy flux. Subsequently, we found that RABV infection induced the reduction of CASP2/caspase 2 and the activation of AMP-activated protein kinase (AMPK)-AKT-MTOR (mechanistic target of rapamycin) and AMPK-MAPK (mitogen-activated protein kinase) pathways. Further investigation revealed that BECN1/Beclin 1 binding to viral phosphoprotein (P) induced an incomplete autophagy via activating the pathways CASP2-AMPK-AKT-MTOR and CASP2-AMPK-MAPK by decreasing CASP2. Taken together, our data first reveals a crosstalk of BECN1 and CASP2-dependent autophagy pathways by RABV infection.
f Human enteric viruses are among the main causative agents of shellfish-associated outbreaks. In this study, the kinetics of viral bioaccumulation in live oysters and the heat stabilities of the predominant enteric viruses were determined both in tissue culture and in oyster tissues. A human norovirus (HuNoV) GII.4 strain, HuNoV surrogates (murine norovirus [MNV-1], Tulane virus [TV]), hepatitis A virus (HAV), and human rotavirus (RV) bioaccumulated to high titers within oyster tissues, with different patterns of bioaccumulation for the different viruses. We tested the thermal stability of each virus at 62, 72, and 80°C in culture medium. The viruses can be ranked from the most heat resistant to the least stable as follows: HAV, RV, TV, MNV-1. In addition, we found that oyster tissues provided protection to the viruses during heat treatment. To decipher the mechanism underlying viral inactivation by heat, purified TV was treated at 80°C for increasing time intervals. It was found that the integrity of the viral capsid was disrupted, whereas viral genomic RNA remained intact. Interestingly, heat treatment leading to complete loss of TV infectivity was not sufficient to completely disrupt the receptor binding activity of TV, as determined by the porcine gastric mucin-magnetic bead binding assay. Similarly, HuNoV virus-like particles (VLPs) and a HuNoV GII.4 strain retained some receptor binding ability following heat treatment. Although foodborne viruses have variable heat stability, 80°C for >6 min was sufficient to completely inactivate enteric viruses in oysters, with the exception of HAV.A pproximately 7.6 million to 14.5 million illnesses in the United States are attributed to the consumption of contaminated seafood each year, and enteric viruses are responsible for more than 50% of these cases (1). In a review of the available epidemiological evidence, human norovirus (HuNoV) and hepatitis A virus (HAV) were the leading viruses associated with shellfish, accounting for 83.7% and 12.8% of outbreaks, respectively (2). The type of shellfish most frequently associated with viral outbreaks was oysters, which were the vehicle in 58.4% of outbreaks (2). In some regions, human enteric viruses are practically ubiquitous in harvested shellfish. Keller et al. (3) showed that 100% of shellfish samples collected from Vitória Bay, Espírito Santo, Brazil, were positive for rotavirus (RV) and adenovirus. However, only 80% of the growing water samples were positive for these pathogens. Viral titers were 400 times higher in the shellfish samples than in the growing water, indicating high levels of natural bioaccumulation (3). In the Galician Rias area, the largest shellfish production area in the European Union, 55% of mussel, clam, and cockle samples were contaminated by HuNoV genogroup I (GI) and GII and HAV (4). Thus, understanding of the ecology and persistence of enteric viruses in shellfish is needed to help prevent future outbreaks.The consumption of uncooked contaminated bivalve shellfish continues to pose a public ...
e Acute gastroenteritis caused by human norovirus is a significant public health issue. Fresh produce and seafood are examples of high-risk foods associated with norovirus outbreaks. Food contact surfaces also have the potential to harbor noroviruses if exposed to fecal contamination, aerosolized vomitus, or infected food handlers. Currently, there is no effective measure to decontaminate norovirus on food contact surfaces. Chlorine dioxide (ClO 2 ) gas is a strong oxidizer and is used as a decontaminating agent in food processing plants. The objective of this study was to determine the kinetics and mechanism of ClO 2 gas inactivation of a norovirus surrogate, murine norovirus 1 (MNV-1), on stainless steel (SS) coupons. MNV-1 was inoculated on SS coupons at the concentration of 10 7 PFU/coupon. The samples were treated with ClO 2 gas at 1, 1.5, 2, 2.5, and 4 mg/liter for up to 5 min at 25°C and a relative humidity of 85%, and virus survival was determined by plaque assay. Treatment of the SS coupons with ClO 2 gas at 2 mg/liter for 5 min and 2.5 mg/liter for 2 min resulted in at least a 3-log reduction in MNV-1, while no infectious virus was recovered at a concentration of 4 mg/liter even within 1 min of treatment. Furthermore, it was found that the mechanism of ClO 2 gas inactivation included degradation of viral protein, disruption of viral structure, and degradation of viral genomic RNA. In conclusion, treatment with ClO 2 gas can serve as an effective method to inactivate a human norovirus surrogate on SS contact surfaces. Human norovirus (NoV) is the most prevalent cause of foodborne illnesses worldwide (1-3). This etiological agent accounts for more than 58% of all foodborne illnesses, causing 5.5 million cases of acute gastroenteritis in the United States annually (1). It is estimated that human NoV is responsible for more than 95% of nonbacterial acute gastroenteritis. Human NoV transmission occurs primarily through the fecal-oral route, either via person-to-person contact or contaminated food, water, fomites, and environmental surfaces (4, 5), and airborne transmission of viral particles may also be possible due to aerosolized vomitus or fecal material (6). Human NoV is highly contagious, with an infectious dose as low as 10 particles, and outbreaks often occur in confined settings, including restaurants, coach buses, hotels, nursing homes, hospitals, and cruise ships (7-11). Although human NoV causes significant health and emotional burdens, research on human NoV has been hampered due to the lack of an in vitro cell culture method and a small animal model (12). Therefore, we must rely on proper surrogates to study the survival of human NoV. Currently, cultivable animal caliciviruses, such as murine norovirus (MNV), feline calicivirus (FCV), and Tulane virus (TV), are used as surrogates for the study of human NoV (13,14). Studies have shown that MNV is more resistant to acid, heat, and environmental stresses than FCV (15). While MNV and TV have similar long-term storage stability and resistance to heat ...
Human norovirus (HuNoV) is a leading cause of foodborne diseases worldwide. High-pressure processing (HPP) is one of the most promising nonthermal technologies for the decontamination of viral pathogens in foods. However, the survival of HuNoVs after HPP is poorly understood because these viruses cannot be propagated in vitro. In this study, we estimated the survival of different HuNoV strains within genogroup II (GII) after HPP treatment using viral receptor-binding ability as an indicator. Four HuNoV strains (one GII genotype 1 [GII.1] strain, two GII.4 strains, and one GII.6 strain) were treated at high pressures ranging from 200 to 600 MPa. After treatment, the intact viral particles were captured by porcine gastric mucin-conjugated magnetic beads (PGM-MBs) that contained histo-blood group antigens, the functional receptors for HuNoVs. The genomic RNA copies of the captured HuNoVs were quantified by real-time reverse transcriptase PCR (RT-PCR). Two GII.4 HuNoVs had similar sensitivities to HPP. The resistance of HuNoV strains against HPP ranked as follows: GII.1 > GII.6 > GII.4, with GII.4 being the most sensitive. Evaluation of temperature and matrix effects on HPP-mediated inactivation of HuNoV GII.4, GII.1, and GII.6 strains showed that HuNoV was more easily inactivated at lower temperatures and at a neutral pH. In addition, phosphate-buffered saline (PBS) and minimal essential medium (MEM) can provide protective effects against HuNoV inactivation compared to H 2 O. Collectively, this study demonstrated that (i) different HuNoV strains within GII exhibited different sensitivities to high pressure, and (ii) HPP is capable of inactivating HuNoV GII strains by optimizing pressure parameters. IMPORTANCEHuman norovirus (HuNoV) is a leading cause of foodborne disease worldwide. Noroviruses are highly diverse, both antigenically and genetically. Genogroup II (GII) contains the majority of HuNoVs, with GII genotype 4 (GII.4) being the most prevalent. Recently, GII.1 and GII.6 have emerged and caused many outbreaks worldwide. However, the survival of these GII HuNoVs is poorly understood because they are uncultivable in vitro. Using a novel receptor-binding assay conjugated with real-time RT-PCR, we found that GII HuNoVs had variable susceptibilities to high-pressure processing (HPP), which is one of the most promising food-processing technologies. The resistance of HuNoV strains to HPP ranked as follows: GII.1 > GII.6 > GII.4. This study highlights the ability of HPP to inactivate HuNoV and the need to optimize processing conditions based on HuNoV strain variability and sample matrix.
Human norovirus (NoV) is a major cause of fresh produce-associated outbreaks and human NoV in irrigation water can potentially lead to viral internalization in fresh produce. Therefore, there is a need to develop novel intervention strategies to target internalized viral pathogens while maintaining fresh produce quality. In this study electron beam (E-beam) and gamma radiation were evaluated for efficacy against a human NoV GII.4 strain and Tulane virus (TV). Virus survival following ionizing radiation treatments was determined using direct quantitative reverse transcriptase PCR (RT-qPCR), the porcine gastric mucin magnetic bead (PGM-MB) binding assay followed by RT-qPCR, and plaque assay. In simple media, a high dose of E-beam treatment was required to completely abolish the receptor binding ability of human NoV (35.3kGy) and TV (19.5-24.1kGy), as assessed using the PGM-MB binding assay. Both human NoV and TV were more susceptible to gamma irradiation than E-beam, requiring 22.4kGy to achieve complete inactivation. In whole strawberries, no human NoV or TV RNA was detected following 28.7kGy of E-beam treatment using the PGM-MB binding assay. Overall, human NoV and TV are highly resistant to ionizing radiation and therefore the technology may not be suitable to eliminate viruses in fresh produce at the currently approved levels. In addition, the PGM-MB binding assay is an improved method to detect viral infectivity compared to direct RT-qPCR.
Hepatitis E Virus (HEV) is endemic in areas with poor sanitation and has traditionally been classified as a water-borne virus. Until recently, cases of HEV in industrialized countries were associated with travel to those areas. In the last decade, locally acquired cases of HEV have increased in the European Union, leading to the investigation of potential foodborne transmission of the virus. In the mid-1990's HEV was found to be unique among other water-and food-borne viruses because of the observation of zoonotic transmission of the virus. HEV is endemic on domestic swine farms worldwide and can infect pigs of all ages. Consequently, pork liver and pork liver containing products have been identified as the source of many of the foodborne HEV outbreaks in Europe. Other pork products and game meats have also been implicated in HEV outbreaks. Finally, anecdotal evidence exists for HEV transmission via shellfish and produce. HEV disease presentation is typically a self-limiting acute hepatitis; however, chronic hepatitis and extrahepatic manifestations occur in high-risk populations. Detection and control of HEV remains challenging because an efficient cell culture system has yet to be developed. Thus, detection relies upon molecular and serological methods. No standardized method exists for the detection of HEV in foods and research on the stability of HEV in foods and the environment has been limited. This review summarizes the current knowledge available on foodborne HEV.
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