H epatitis B virus (HBV) infection is a major health problem.There are more than 350 million chronic carriers worldwide, and they are at high risk of developing liver cirrhosis and hepatocellular carcinoma (1). Chronic HBV infection is the result of impaired HBV-specific immune responses such that the infected hepatocytes cannot be eliminated or cured efficiently, but many of the associated issues remain unclear (2, 3).Due to the paucity of in vitro and in vivo models for HBV infection, HBV-transgenic mice are the most widely used model. These mice have the viral genome integrated into the chromosome and produce infectious HBV particles or viral antigens in the liver; however, the main limitation of HBV-transgenic mouse models is that they are immunologically tolerant to viral antigens (4, 5). Various routes have been exploited to introduce the HBV genome into the hepatocytes of adult mice. One is to introduce a replication-competent HBV genome into the mouse liver by hydrodynamic injection (HDI) through the tail vein (6); although HBV replicates in the mouse liver, the virus is rapidly cleared by immune responses against HBV proteins (7). Recently, Huang and colleagues used HDI to create a nontransgenic model of persistent HBV replication (8). The virus persisted in 40% of mice or was eliminated according to the genetic background. These mice rapidly develop anti-hepatitis B virus core (HBc) antibody, which is the first serological marker of acute HBV infection in humans. An alternative method uses adenoviral vectors to transfer 1.3 copies of the HBV genome into immunocompetent mice (9, 10), and acute or chronic HBV infection was obtained depending on the dose of adenoviral vector injected.Here, we describe an alternative murine model for the study of HBV persistence based on the liver-targeted transduction of adeno-associated virus serotype 2/8 (AAV2/8). We produced an AAV2/8 construct carrying a replication-competent HBV DNA genome and by intravenous injection established a model of HBV persistence in humanized HLA-A2/DR1 immunocompetent mice. Hepatitis B virus surface antigen (HBsAg), hepatitis B virus e antigen (HBeAg), and HBV DNA persisted for at least 1 year in sera of all AAV2/8-injected mice, and viral replication intermediates and transcripts were detected in their livers. HBcAg was expressed in 60% of hepatocytes without significant inflammation in the liver. The persistence of infection was associated with the presence of regulatory T cells (Tregs) in the liver. This mouse model of HBV persistence recapitulates viral and histological characteristics of human chronic HBV infection in the immunetolerant stage of the disease (11,12).In HLA-A2/DR1 mice, cellular immune responses were completely restricted to HLA molecules. Antibody, T-helper, and cytotoxic-T-lymphocyte responses to vaccination with recombinant HBsAg or HBsAg-expressing DNA were similar to those in vaccinated humans (13,14) or in HBV-infected individuals (15). Therefore, this AAV2/8-HBV-transduced HLA-A2/DR1 murine model may be useful fo...
Background Animal models have demonstrated that allergen-specific IgG confers sensitivity to systemic anaphylaxis that relies on IgG receptors (FcγRs). Mouse IgG2a and IgG2b bind activating FcγRI, FcγRIII and FcγRIV, and inhibitory FcγRIIB; mouse IgG1 binds only FcγRIII and FcγRIIB. Although these interactions are of strikingly different affinities, these three IgG subclasses have been shown to enable induction of systemic anaphylaxis. Objective Determine which pathways control the induction of IgG1-, IgG2a- and IgG2b-passive systemic anaphylaxis. Methods Mice were sensitized with IgG1, IgG2a or IgG2b anti-TNP mAbs and challenged with TNP-BSA intravenously to induce systemic anaphylaxis that was monitored using rectal temperature. Anaphylaxis was evaluated in mice deficient for FcγRs, injected with mediator antagonists or in which basophils, monocyte/macrophages or neutrophils had been depleted. The expression of FcγRs was evaluated on these cells before and after anaphylaxis. Results Activating FcγRIII is the receptor primarily responsible for all three models of anaphylaxis, and subsequent down regulation of this receptor was observed. These models differentially relied on histamine release and on the contribution of mast cells, basophils, macrophages and neutrophils. Strikingly, basophil contribution and histamine predominance in IgG1- and IgG2b-mediated anaphylaxis correlated with the ability of inhibitory FcγRIIB to negatively regulate these models of anaphylaxis. Conclusion We propose that the differential expression of inhibitory FcγRIIB on myeloid cells and its differential binding of IgG subclasses controls the contributions of mast cells, basophils, neutrophils and macrophages to IgG subclass-dependent anaphylaxis. Collectively, our results unravel novel complexities in the involvement and regulation of cell populations in IgG-mediated reactions in vivo.
Platelets are key regulators of vascular integrity; however, their role in anaphylaxis, a life-threatening systemic allergic reaction characterized by the loss of vascular integrity and vascular leakage, remains unknown. Anaphylaxis is a consequence of inappropriate cellular responses triggered by antibodies to generally harmless antigens, resulting in a massive mediator release and rapidly occurring organ dysfunction. Human platelets express receptors for immunoglobulin G (IgG) antibodies and can release potent mediators, yet their contribution to anaphylaxis has not been previously addressed in mouse models, probably because mice do not express IgG receptors on platelets. We investigated the contribution of platelets to IgG-dependent anaphylaxis in human IgG receptor-expressing mouse models and a cohort of patients suffering from drug-induced anaphylaxis. Platelet counts dropped immediately and markedly upon anaphylaxis induction only when they expressed the human IgG receptor FcγRIIA/CD32A. Platelet depletion attenuated anaphylaxis, whereas thrombocythemia substantially worsened its severity. FcγRIIA-expressing platelets were directly activated by IgG immune complexes in vivo and were sufficient to restore susceptibility to anaphylaxis in resistant mice. Serotonin released by activated platelets contributed to anaphylaxis severity. Data from a cohort of patients suffering from drug-induced anaphylaxis indicated that platelet activation was associated with anaphylaxis severity and was accompanied by a reduction in circulating platelet numbers. Our findings identify platelets as critical players in IgG-dependent anaphylaxis and provide a rationale for the design of platelet-targeting strategies to attenuate the severity of anaphylactic reactions.
ObjectiveTo assess a new adenovirus-based immunotherapy as a novel treatment approach to chronic hepatitis B (CHB).MethodsTG1050 is a non-replicative adenovirus serotype 5 encoding a unique large fusion protein composed of a truncated HBV Core, a modified HBV Polymerase and two HBV Envelope domains. We used a recently described HBV-persistent mouse model based on a recombinant adenovirus-associated virus encoding an over length genome of HBV that induces the chronic production of HBsAg, HBeAg and infectious HBV particles to assess the ability of TG1050 to induce functional T cells in face of a chronic status.ResultsIn in vitro studies, TG1050 was shown to express the expected large polyprotein together with a dominant, smaller by-product. Following a single administration in mice, TG1050 induced robust, multispecific and long-lasting HBV-specific T cells detectable up to 1 year post-injection. These cells target all three encoded immunogens and display bifunctionality (ie, capacity to produce both interferon γ and tumour necrosis factor α as well as cytolytic functions). In addition, control of circulating levels of HBV DNA and HBsAg was observed while alanine aminotransferase levels remain in the normal range.ConclusionsInjection of TG1050 induced both splenic and intrahepatic functional T cells producing cytokines and displaying cytolytic activity in HBV-naïve and HBV-persistent mouse models together with significant reduction of circulating viral parameters. These results warrant clinical evaluation of TG1050 in the treatment of CHB.
The pharmacokinetic properties of antibodies are largely dictated by the pH-dependent binding of the IgG fragment crystallizable (Fc) domain to the human neonatal Fc receptor (hFcRn). Engineered Fc domains that confer a longer circulation half-life by virtue of more favorable pH-dependent binding to hFcRn are of great therapeutic interest. Here we developed a pH Toggle switch Fc variant containing the L309D/Q311H/N434S (DHS) substitutions, which exhibits markedly improved pharmacokinetics relative to both native IgG1 and widely used half-life extension variants, both in conventional hFcRn transgenic mice and in new knock-in mouse strains. engineered specifically to recapitulate all the key processes relevant to human antibody persistence in circulation, namely: (i) physiological expression of hFcRn, (ii) the impact of hFcγRs on antibody clearance and (iii) the role of competing endogenous IgG. DHS-IgG retains intact effector functions, which are important for the clearance of target pathogenic cells and also has favorable developability.
Gain-of-function mutations in NLRP3 are responsible for a spectrum of autoinflammatory diseases collectively referred to as “cryopyrin-associated periodic syndromes” (CAPS). Treatment of CAPS patients with IL-1–targeted therapies is effective, confirming a central pathogenic role for IL-1β. However, the specific myeloid cell population(s) exhibiting inflammasome activity and sustained IL-1β production in CAPS remains elusive. Previous reports suggested an important role for mast cells (MCs) in this process. Here, we report that, in mice, gain-of-function mutations in Nlrp3 restricted to neutrophils, and to a lesser extent macrophages/dendritic cells, but not MCs, are sufficient to trigger severe CAPS. Furthermore, in patients with clinically established CAPS, we show that skin-infiltrating neutrophils represent a substantial biological source of IL-1β. Together, our data indicate that neutrophils, rather than MCs, can represent the main cellular drivers of CAPS pathology.
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