Infection Dynamics of Hepatitis E Virus in Wild-Type and Immunoglobulin Heavy Chain Knockout JH-/- Gnotobiotic Piglets.

Hepatitis E virus (HEV), the causative agent of hepatitis E, is an important but incompletely understood pathogen causing high mortality during pregnancy and leading to chronic hepatitis in immunocompromised individuals. The underlying mechanisms leading to hepatic damage remain unknown; however, the humoral immune response is implicated. In this study, immunoglobulin (Ig) heavy chain JH-/- knockout gnotobiotic pigs were generated using CRISPR/Cas9 technology to deplete the B-lymphocyte population, resulting in an inability to generate a humoral immune response to genotype 3 HEV infection. Compared to wild-type gnotobiotic piglets, the frequencies of B lymphocytes in the Ig heavy chain JH-/- knockouts were significantly lower, despite similar levels of other innate and adaptive T-lymphocyte cell populations. The dynamic of acute HEV infection was subsequently determined in heavy chain JH-/- knockout and wild-type gnotobiotic pigs. The data showed that wild-type piglets had higher viral RNA loads in feces and sera compared to the JH-/- knockout pigs, suggesting that the Ig heavy chain JH-/- knockout in pigs actually decreased the level of HEV replication. Both HEV-infected wild-type and JH-/- knockout gnotobiotic piglets developed more pronounced lymphoplasmacytic hepatitis and hepatocellular necrosis lesions than other studies with conventional pigs. The HEV-infected JH-/- knockout pigs also had significantly enlarged livers both grossly and as a ratio of liver/body weight compared to phosphate-buffered saline-inoculated groups. This novel gnotobiotic pig model will aid in future studies into HEV pathogenicity, an aspect which has thus far been difficult to reproduce in the available animal model systems.IMPORTANCE According to the World Health Organization, approximately 20 million HEV infections occur annually, resulting in 3.3 million cases of hepatitis E and >44,000 deaths. The lack of an efficient animal model that can mimic the full-spectrum of infection outcomes hinders our ability to delineate the mechanism of HEV pathogenesis. Here, we successfully generated immunoglobulin heavy chain JH-/- knockout gnotobiotic pigs using CRISPR/Cas9 technology, established a novel JH-/- knockout and wild-type gnotobiotic pig model for HEV, and systematically determined the dynamic of acute HEV infection in gnotobiotic pigs. It was demonstrated that knockout of the Ig heavy chain in pigs decreased the level of HEV replication. Infected wild-type and JH-/- knockout gnotobiotic piglets developed more pronounced HEV-specific lesions than other studies using conventional pigs, and the infected JH-/- knockout pigs had significantly enlarged livers. The availability of this novel model will facilitate future studies of HEV pathogenicity.

A Lipid/DNA Adjuvant-Inactivated Influenza Virus Vaccine Protects Rhesus Macaques From Uncontrolled Virus Replication After Heterosubtypic Influenza A Virus Challenge.

Background: Influenza A virus (IAV) vaccines offer little protection from mismatched viruses with antigenically distant hemagglutinin (HA) glycoproteins. We sought to determine if a cationic lipid/DNA complex (CLDC) adjuvant could induce heterosubtypic protection if added to a whole inactivated IAV vaccine (WIV). Methods: Adult rhesus macaques (RMs) were vaccinated and at 2 weeks boosted with either an H1N1-WIV or an H3N2-WIV, with and without CLDC adjuvant. Four weeks postboost, animals were challenged with an H1N1 IAV matched to the H1N1-WIV vaccine. Results: After challenge, viral RNA (vRNA) levels in the trachea of control RMs and RMs vaccinated with the unadjuvanted H1 or H3 WIV vaccines were similar. However, vRNA levels in the trachea of both the H1-WIV/CLDC- and the H3-WIV/CLDC-vaccinated RMs (P < 0.01 and P < 0.05, respectively) were significantly lower than in unvaccinated control RMs. Heterosubtypic protection in H3-WIV/CLDC RMs was associated with significantly higher levels of nucleoprotein (NP) and matrix-1-specific immunoglobulin G antibodies (P < 0.05) and NP-specific nonneutralizing antibody-dependent natural killer cell activation (P < 0.01) compared with unprotected H3-WIV RMs. Conclusions: Addition of the CLDC adjuvant to a simple WIV elicited immunity to conserved virus structural proteins in RMs that correlate with protection from uncontrolled virus replication after heterosubtypic influenza virus challenge.

Isolation of Peripheral Blood CD8 T Cells Specific to Porcine Reproductive and Respiratory Syndrome Virus Utilizing Porcine CD137 Activation Marker.

CD137 is a costimulatory molecule transiently expressed on activated T cells after mitogen or antigen stimulation that can be exploited for isolating antigen-specific T cells as reported in mouse models. By utilizing an antiporcine CD137 monoclonal antibody (mAb, clone 3B9) developed in our laboratory, we isolated virus-specific CD8ß T cells from peripheral blood of pigs experimentally infected with different porcine reproductive and respiratory syndrome virus (PRRSV) strains. Similar to mouse, porcine CD8ß T cells also express CD137 transiently upon Concavalin A stimulation while the unstimulated cells did not. Most frequently, virus-specific CD8ß T cells were isolated at low levels from peripheral blood of pigs experimentally infected with PRRSV strains VR2385, NADC20, and MN184B at 49 and 63 days postinfection. The results suggest that porcine CD137-specific mAb is a useful tool for isolating virus-specific CD8 T cells from peripheral blood and tissues of pigs after in vitro stimulation with viral antigen.

Myxovirus resistance gene A (MxA) expression suppresses influenza A virus replication in alpha interferon-treated primate cells.

Alpha interferon (IFN-α) production is triggered when influenza virus RNA is detected by appropriate pattern recognition receptors in the host cell. IFN-α induces the expression of more than 300 interferon-stimulated genes (ISGs), and this blunts influenza virus replication. The human ISG MxA can inhibit influenza A virus replication in mouse cells by interfering with a step in the virus replication cycle after primary transcription of the negative-strand RNA genome to mRNA (J. Pavlovic, O. Haller, and P. Staeheli, J. Virol. 66:2564-2569, 1992). To determine the role of MxA in blocking human influenza A virus replication in primate cells, we manipulated MxA expression in rhesus kidney epithelial cells (LLC-MK(2)) and human lung carcinoma cells (A549). We found that IFN-α treatment prior to influenza virus infection suppressed virus replication and induced the expression of many ISGs, including MxA. However, IFN-α-mediated suppression of virus replication was abolished by small interfering RNA (siRNA) knockdown of MxA expression in IFN-treated cells. In addition, influenza virus replication was suppressed in Vero cells stably transfected with MxA. A strand-specific reverse transcription-PCR (RT-PCR) assay showed that positive-strand influenza virus mRNA and negative-strand genomic RNA (gRNA) accumulated to high levels at 8 h after infection in control Vero cells containing the empty vector. However, in Vero cells stably transfected with MxA positive-strand influenza virus mRNA, complementary positive-strand influenza virus genome RNA (cRNA) and influenza virus gRNA were drastically suppressed. Thus, in primate cells, MxA inhibits human seasonal influenza virus replication at a step prior to primary transcription of gRNA into mRNA. Taken together, these results demonstrate that MxA mediates control of influenza virus replication in primate cells treated with IFN-α.

Memory B cells and CD8⁺ lymphocytes do not control seasonal influenza A virus replication after homologous re-challenge of rhesus macaques.

This study sought to define the role of memory lymphocytes in the protection from homologous influenza A virus re-challenge in rhesus macaques. Depleting monoclonal antibodies (mAb) were administered to the animals prior to their second experimental inoculation with a human seasonal influenza A virus strain. Treatment with either anti-CD8α or anti-CD20 mAbs prior to re-challenge had minimal effect on influenza A virus replication. Thus, in non-human primates with pre-existing anti-influenza A antibodies, memory B cells and CD8α⁺ T cells do not contribute to the control of virus replication after re-challenge with a homologous strain of influenza A virus.