治疗模式识别受体激动剂治疗慢性乙型肝炎的现状与潜力治

StephenW

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Treatment of chronic hepatitis B with pattern recognition receptor agonists: Current status and potential for a cure

    Jinhong Chang, , Ju-Tao Guo

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        doi:10.1016/j.antiviral.2015.07.006
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Highlights

•    Hepatitis B virus (HBV) infection can be sensed by pattern recognition receptors.
•    Interferons, TNF-α and IL-1β inhibit HBV replication via distinct mechanisms.
•    Intrahepatic innate immune responses determine the outcome of HBV infection.
•    Intrahepatic activation of TLR7/8/9 or the STING response holds great promise for the cure of chronic hepatitis B.

Abstract

Hepatitis B virus (HBV) has been considered to be a “stealth virus” that induces negligible innate immune responses during the early phase of infection. However, recent studies with newly developed experimental systems have revealed that virus infection can be recognized by pattern recognition receptors (PRR), eliciting a cytokine response that controls the replication of the virus. The molecular mechanisms by which interferons and other inflammatory cytokines suppress HBV replication and modulate HBV cccDNA metabolism and function are just beginning to be revealed. In agreement with the notion that the developmental and functional status of intrahepatic innate immunity determines the activation and maturation of the HBV-specific adaptive immune response and thus the outcome of HBV infection, pharmacological activation of intrahepatic innate immune responses with TLR7/8/9 or STING agonists efficiently controls HBV infection in preclinical studies and thus holds great promise for the cure of chronic hepatitis B. This article forms part of a symposium in Antiviral Research on “An unfinished story: from the discovery of the Australia antigen to the development of new curative therapies for hepatitis B.”
Keywords

    Hepatitis B virus; Innate immune response; Cytokine; Pattern recognition receptor agonist

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回顾
治疗模式识别受体激动剂治疗慢性乙型肝炎的现状与潜力治愈

    张金红，菊郭涛

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        DOI：10.1016 / j.antiviral.2015.07.006
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亮点

•乙型肝炎病毒（HBV）感染可通过模式识别受体被感测。
•经由不同的机制干扰素，TNF-α和IL-1β抑制HBV复制。
•肝内先天免疫反应测定乙肝病毒感染的结果。
•TLR7 / 8/9或刺痛反应的激活肝内为持有慢性乙型肝炎的治疗大有希望

抽象

乙型肝炎病毒（HBV）已被认为是一个“隐形病毒”，在感染的早期阶段诱导微不足道先天免疫反应。然而，最近的研究，新开发的实验系统揭示，病毒感染可通过模式识别受体（PRR），引发细胞因子响应，控制病毒的复制被识别。由干扰素等炎性细胞因子抑制HBV的复制和调节HBV cccDNA的代谢和功能的分子机制才刚刚开始显露出来。与概念，即肝内先天免疫的发育和功能状态确定的激活和HBV特异性适应性免疫应答的成熟，因此HBV感染的结果，与TLR7肝内先天免疫反应/ 8/9或药理学的激活协议STING激动剂有效控制乙肝病毒感染的临床前研究，从而为持有慢性乙型肝炎的治疗本文形式的抗病毒研究的专题讨论会的一部分，对“一个未完成的故事，伟大的承诺：从澳大利亚抗原的发现到新的发展根治疗法为乙型肝炎“
关键词

    乙型肝炎病毒;先天免疫应答;细胞因子;模式识别受体激动剂

StephenW

  Fig. 1.

    Interferons and other inflammatory cytokines control HBV infection of hepatocytes via multiple, distinct mechanisms. The viral replication cycle and cytokine-induced molecular pathways in hepatocytes are illustrated and explained in detail in the text. Sequential replication steps are highlighted with red lines. IFNs bind to their receptors on hepatocytes to trigger the JAK-STAT signaling pathway and induce the expression of ISGs (green lines), which control HBV replication via inhibition of pgRNA encapsidation and cccDNA transcription, as well as the elimination of cccDNA (black lines). TNF-α and IL-1β bind to their cognate receptors to activate the NF-κB pathway, inducing expression of AID (blue lines), which restricts HBV entry into hepatocytes and suppresses viral replication (black lines).
图。1。

    干扰素等炎性细胞因子控制乙肝病毒感染的肝细胞通过多种，不同的机制。病毒复制周期和细胞因子诱导的分子途径在肝细胞中被示出和详细的文字说明。连续复制步骤都突出了红线。干扰素结合到它们的受体上的肝细胞，以触发JAK-STAT信号传导途径，诱导的ISG（绿线），其通过抑制pgRNA壳体化和cccDNA的转录控制HBV复制的表达，以及消除的cccDNA的（黑线） 。 TNF-α和IL-1β结合到其同源受体激活的NF-κB途径，诱导AID的表达（蓝线），这限制了乙肝病毒进入肝细胞并抑制病毒复制（黑线）。

StephenW

6.1. TLR7 agonists

GS-9620, a potent and orally available TLR7 agonist, is the front runner of PRR agonists under development for treatment of chronic hepatitis B. Its great therapeutic potential has been demonstrated in preclinical studies in woodchucks infected with woodchuck hepatitis virus (WHV) and HBV-infected chimpanzees. Specifically, treatment of woodchucks chronically infected by WHV with varying dose frequencies of GS-9620 for 4–8 weeks resulted in a greater than 6 log reduction of viral load. Intriguingly, while 15 out of 19 animals had dramatic viral load reductions during treatment, the suppressive effect on viral load was sustained in 12 of these 15 animals, and 13 of the 15 sustained WHsAg loss after cessation of treatment. Moreover, for those with sustained WHsAg loss, 8 of 13 developed an antibody against the surface antigen (Menne et al., 2015). This result is in marked contrast to treatment with nucleoside analogs and IFN-α, which rarely resulted in WHsAg seroconversion (Fletcher et al., 2012 and Menne and Cote, 2007). Mechanism of action studies suggested that consistent with activation of TLR-7 signaling, the antiviral response induced by GS-9620 is likely mediated by both the cytolytic activity of CD8+ T cells and/or NK cells, and type I/II IFN-mediated non-cytolytic activity, as well as activation of B cells, in the liver microenvironment.

In a chimpanzee study, GS-9620 treatment of three HBV chronically infected animals for 8 weeks also reduced viral load by more than 2 logs and resulted in greater than a 50% reduction in HBsAg and HBeAg serum levels. While reduction of viral load by 1 log persisted, no HBsAg seroconversion occurred in any of the treated animals (Lanford et al., 2013). Although IFN-α was transiently induced, the suppression of HBV/HBsAg coincided with NK/T cell activation. Hence, it is most likely that the TLR-7 therapeutic effect relies on not only induction of IFNs, but also activation of other branches of intrahepatic innate immune responses.

Pharmacokinetic and pharmacodynamic studies in healthy volunteers suggested that at low oral doses, GS-9620 induces a type I interferon-dependent antiviral innate immune response without the induction of systemic IFN-α. This presystemic response is likely due to its high intestinal absorption and activation of TLR7 locally via oral administration ( Fosdick et al., 2014). In two phase 1b studies reported recently, one or two low doses of GS-9620 administered once a week were safe and well tolerated ( Gane et al., 2015). However, phase 1 studies did not show evidence of clinical efficacy of GS-9620 in terms of HBV DNA decline, HBsAg reduction ( Gane et al., 2015) or decrease in HCV RNA ( Lawitz et al., 2014). Further clinical investigations are certainly warranted to optimize the dosage and treatment schedules.
6.2. TLR8 agonists

A recent report indicates that TLR8 is a more important PRR than TLR7 in human livers (Jo et al., 2014). Specifically, TLR8 agonist ssRNA40 selectively activated liver-resident, and to a lesser extent, the blood-derived, NKT mucosal-associated invariant T and CD56 (bright) NK cells to produce IFN-γ in both healthy livers and HBV- or HCV-infected livers. This was mediated by the production of IL-12 and IL-18 by intrahepatic monocytes. This work thus suggests that TLR8 agonists might be ideal candidates to activate intrahepatic immunity in patients with chronic hepatitis B (Jo et al., 2014).
6.3. TLR3 agonists

A recent report showed that intrahepatic delivery of poly(I:C), a TLR3 agonist, by hydrodynamic injection, efficiently enhanced intrahepatic innate and adaptive immune responses, and accelerated the clearance of HBV in a mouse model established by the hydrodynamic injection of pAAV–HBV1.2 (Wu et al., 2014). The clearance of HBV was dependent on both type I and type II IFNs, indicating a coordinated action of innate and adaptive immune responses. Moreover, T cell recruitment appeared to be critical for the success of TLR3-mediated antiviral action. These findings suggest that intrahepatic delivery of TLR3 agonists might have a good potential for treating chronic hepatitis B.
6.4. TLR9 agonists

The liver is an immunologically unique organ, with many layers of inhibitory mechanisms that prevent the local population expansion and execution of effector functions of CTLs. This may protect the infected liver from over whelming immunopathology, but may also functionally compromise pathogen-specific CTLs and favor the development of chronic infection (Knolle and Thimme, 2014 and Pallett et al., 2015). An elegant study reported by Knolle’s laboratory recently showed that treatment of mice with the agonist of TLR9, but not TLR3 or TLR7, induced the formation of intrahepatic CD11b+MHCII+ myeloid cell aggregates, designated by the authors as “intrahepatic myeloid-cell aggregates for T cell population expansion” (iMATEs), that support massive expansion of the CTL population locally in the liver (Huang et al., 2013). The iMATEs rapidly formed within 2 days after TLR9 agonist injection and provided an anatomic structure for local proliferation of CTLs dependent on the T-cell costimulatory receptor OX40.

Intriguingly, acute but not chronic lymphocytic choriomeningitis virus (LCMV) infection induced intrahepatic iMATEs formation. However, TLR9 agonist treatment of mice chronically infected with LCMV resulted in iMATEs formation and expansion of virus-specific CLTs and subsequent control of infection. Furthermore, using a model of chronic HBV infection of immunocompetent mice established by Ad-HBV infection (Huang et al., 2012), the authors showed that injection of TLR9 agonist at day 12 after vaccination with a plasmid expressing HBcAg resulted in expansion of the H-2 Kb-restricted CTL population specific for HBcAg amino acids 93–100 (HBc93) in the livers of the mice. The antiviral immune response reduced HBV antigenemia and eventually eliminated HBV-replicating hepatocytes (Huang et al., 2013). This work implies that a combination of DNA vaccination and TLR9 agonist therapy induces intrahepatic iMATEs-facilitated expansion of the vaccination-induced HBV-specific CTL population, which subsequently resolves chronic HBV infection.
6.5. STING agonists

Stimulator of interferon genes (STING) is the adaptor protein of multiple cytoplasmic DNA receptors and a PRR recognizing the bacterial second messengers, cyclic di-adenosine monophosphate (c-di-AMP) and cyclic di-guanosine monophosphate (c-di-GMP) (Burdette and Vance, 2013). It was discovered recently that cytoplasmic DNA activates cyclic guanosine monophosphate-adenosine monophosphate synthase (cGAS) to produce cGAMP, which subsequently binds to STING and induces IFNs and other cytokines (Gao et al., 2013 and Ishikawa and Barber, 2008). The fact that STING can be activated by cyclic di-nucleotides implies that like TLR7 and TLR8, STING might be activated by other small molecules and thus be a potential target for pharmacological activation of innate immune responses, as well as priming of an adaptive immune response.

Indeed, we recently showed that 5,6-dimethylxanthenone-4-acetic acid (DMXAA), a mouse STING agonist, induced a type I-IFN-dominant cytokine response in macrophages, which potently suppressed HBV replication in mouse hepatocytes by reducing the amount of cytoplasmic viral nucleocapsids. Moreover, intraperitoneal administration of DMXAA significantly induced the expression of IFN-stimulated genes and reduced HBV DNA replication intermediates in the livers of HBV-hydrodynamically injected mice. Our study thus provides proof of concept that activation of the STING pathway induces a potent innate antiviral response, and that the development of small-molecule human STING agonists as immunotherapeutic agents for the treatment of chronic hepatitis B is warranted (Guo et al., 2015).

Many PRR agonists have thus far been tested in animal models or in clinical studies for their effects on chronic viral infections of the liver, including hepatitis B. Although promising results have been obtained, the search for the proper agonists that fine-tune host immune responses and cure chronic HBV infection is still under way. In addition, there are many studies reporting HBV evasion and antagonization of innate immune pathways under certain experimental conditions (reviewed in (Chang et al., 2012)). Further investigation is required to re-examine such phenomena in the context of viral replication and in human hepatocytes during natural infection. If confirmed, pharmacological interruption of HBV antagonism of host innate immune responses should be an ideal therapeutic strategy to restore innate, and possibly also adaptive immunity to HBV infection.

StephenW

6.1。 TLR7激动剂

GS-9620，一种有效的和可口服的TLR7激动剂，正在开发PRR激动剂用于治疗慢性乙型肝炎及其巨大的治疗潜力已被证明在临床前研究中感染土拨鼠肝炎病毒（WHV）土拨鼠和HBV前转轮 - 感染黑猩猩。具体而言，治疗旱獭的慢性感染由WHV具有变化的GS-9620的剂量频率为4-8周导致病毒载量的一个大于6对数减少。有趣的是，尽管在治疗过程中的15项19的动物具有戏剧性的病毒载量的减少，对病毒载量的抑制效果持续在这些15只动物的12和13中的15的持续WHsAg损失停止治疗后。此外，对于那些与持续WHsAg损失，8月13日的开发的一种抗体针对表面抗原（Menne等人，2015）。这一结果是在鲜明对比治疗与核苷类似物和IFN-α，而很少导致WHsAg血清转变（Fletcher等人，2012和Menne和科特，2007）。的作用的研究机构提出，以活化TLR-7信令一致，诱导由GS-9620的抗病毒反应很可能是由CD8 + T细胞和/或NK细胞两种细胞溶解活性，和类型介导的I / II型干扰素介导的非-cytolytic活性，以及​​激活的B细胞，在肝脏微环境。

在一个黑猩猩研究中，GS-9620治疗3的HBV慢性感染的动物，持续8周也减少病毒载量超过2日志并且导致大于HBsAg和HBeAg血清水平降低了50％。而由1个对数减少病毒载量的持续存在，没有HBsAg血清发生在任何处理的动物（兰福德等人，2013年）。虽然IFN-α诱导短暂，HBV / HBsAg的抑制恰逢NK / T细胞活化。因此，它是最有可能的是，TLR-7的治疗效果依赖于不仅诱导IFN的，而且还激活肝内先天免疫反应的其他分支。

药动学和在健康志愿者中的药效学研究表明，在低的口服剂量，GS-9620诱导的I型干扰素依赖性抗病毒先天免疫没有全身的IFN-α的诱导响应。这个系统前响应可能是由于它的高的肠道吸收，并激活TLR7的局部通过口服给药（福斯迪克等人，2014年）。在两相1B研究报道近日，一个或两个低剂量GS-9620的每周给药一次，是安全和耐受性良好（甘恩等人，2015年）。然而，第1阶段的研究并没有表明GS-9620的临床疗效中的HBV DNA的下降，HBsAg的减小方面的证据（甘恩等人，2015）或减少丙型肝炎病毒RNA（Lawitz等人，2014年）。进一步的临床调查是肯定必要的，以优化的剂量和治疗方案。
6.2。 TLR8激动剂

最近的报告表明，TLR8比TLR7在人肝脏（Jo等人，2014年）的更重要的PRR。具体地讲，TLR8激动剂ssRNA40选择性地激活肝驻留，以及在较小程度上，血液衍生，NKT粘膜相关不变T和CD56（亮）的NK细胞产生的IFN-γ在健康肝脏和HBV-或HCV-感染的肝脏。这是通过产生IL-12和IL-18的肝内单核细胞介导的​​。这项工作因此表明，TLR8激动剂可能是理想人选，以激活慢性乙型肝炎肝内免疫（曹某等人，2014年）。
6.3。 TLR3激动剂

最近的一份报告显示，肝内交付聚（I：C），一个TLR3激动剂，通过流体力学注射，有效提高肝内固有免疫和适应性免疫反应，加速乙肝病毒的清除由高压注射pAAV-建立了小鼠模型HBV1.2（吴等人，2014年）。乙肝病毒的清除率是依赖于I型和II型干扰素，说明的先天和适应性免疫反应以协调动作。此外，T细胞募集似乎是对TLR3介导的抗病毒作用的成功至关重要。这些结果表明，肝内递送TLR3激动剂可能有一个良好的潜力用于治疗慢性乙型肝炎
6.4。 TLR9激动剂

肝脏是免疫器官独特，具有防止当地人口膨胀和执行的CTL效应功能抑制机制多种层次。这可保护感染的肝从超过空前免疫病理学，但也可在功能上妥协病原体特异的CTL和利于慢性感染的发展（Knolle和Thimme，2014年和Pallett等人，2015）。报道Knolle实验室一项出色的研究最近发现，治疗小鼠的TLR9的激动剂，但不是TLR3或TLR7，诱导形成肝内的CD11b + MHCII +骨髓细胞聚集体，由作者指定为“肝内髓细胞聚集对于T细胞人口膨胀“（的iMate），支持CTL人口的大规模扩张局部在肝脏（Huang等，2013）。 TLR9激动剂注射后2天内的iMate迅速形成并用于CTL的局部增殖依赖于T细胞共刺激受体OX40提供解剖结构。

有趣的是，急性但不是慢性淋巴细胞性脉络丛脑膜炎病毒（LCMV）感染引起的肝内形成的iMate。然而，慢性感染LCMV小鼠TLR9激动剂治疗导致的iMate形成和扩大的病毒特异性CLTS和随后的控制感染。此外，使用慢性HBV感染的Ad-HBV感染免疫建立小鼠模型（Huang等，2012）中，作者发现，注射TLR9激动剂在12天的接种核心抗原表达质粒后导致扩张H-2 KB限制性CTL种群特异性针对HBcAg的氨基酸93-100（HBc93）在小鼠的肝脏。抗病毒免疫应答降低的HBV抗原，并最终消除HBV的复制型肝细胞（Huang等人，2013年）。这项工作表明DNA疫苗和TLR9激动剂治疗相结合的诱导免疫诱导的HBV特异性CTL人口，随后解决了慢性HBV感染者肝内的iMate，促进扩大。
6.5。 STING激动剂

干扰素基因（STING）的刺激物是多个细胞质的DNA受体和适配器蛋白质PRR识别细菌第二信使，环二磷酸腺苷（三二 - AMP）和环状二磷酸鸟苷（三二 - GMP） （Burdette和万斯，2013）。它最近被发现细胞质DNA激活环磷酸鸟苷 - 磷酸腺苷酶（CGA）的生产cGAMP，随后结合STING并诱导干扰素等细胞因子（Gao等，2013年和石川和理发，2008）。事实STING可以通过环状二核苷酸被激活意味着像​​TLR7和TLR8，STING可能是由其它小分子活化，因而是先天免疫反应的药理学激活的潜在目标的适应性免疫应答，以及引发。

事实上，我们最近发现，5,6-二甲基-4-乙酸（DMXAA），鼠标STING激动剂，诱导型巨噬细胞中的I-IFN-主导的细胞因子应答，其通过减少量有力地抑制在小鼠肝细胞中HBV复制细胞质核衣壳病毒。此外，DMXAA的腹腔内给药显著诱导的IFN激活基因和减少HBV DNA复制中间体的表达中的HBV-流体动力学注射的小鼠的肝脏中。我们的研究提供了这样的概念，激活STING途径诱导有效的先天抗病毒反应的证明，以及小分子STING人作为兴奋剂免疫治疗剂的发展为慢性乙型肝炎的治疗是必要的（Guo等，2015年）。

许多PRR激动剂迄今在动物模型或在其对肝脏的慢性病毒感染，包括乙型肝炎效果的临床研究进行了测试虽然有希望的结果已获得的搜索该微调宿主免疫应答的合适的激动剂和治疗慢性HBV感染仍在进行中。此外，还有很多研究报告HBV逃税和先天免疫途径antagonization在一定的实验条件下（综述（Chang等，2012））。进一步的调查，需要在病毒复制的上下文中和在自然感染过程中的人肝细胞重新检查等现象。如果得到证实，宿主天然免疫应答HBV对立的药理中断应该是一个理想的治疗策略，以恢复与生俱来的，也可能适应性免疫HBV感染。

StephenW

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