乙肝病毒和细胞凋亡抑制蛋白 - 一个弱势联络

StephenW

Cell Death Discovery | Editorial Open

  
Hepatitis B virus and inhibitor of apoptosis proteins – a vulnerable liaison

    G Ebert  & M Pellegrini

      Cell Death Discovery 2, Article number: 16014 (2016) ​doi:10.1038/cddiscovery.2016.14

Published online
    22 February 2016


Subject terms:

    Apoptosis • Cell death and immune response • Hepatitis B • Target identification • Translational research

Hepatitis B infection and current therapies

    Hepatitis B infection and current therapies • TNF signalling and HBV infection • HBV and IAPs – a vulnerable liaison • References • Author information

The treatment for hepatitis C virus (HCV) infection has been revolutionized by the introduction of highly potent antiviral drugs that can successfully cure most patients.1 A major distinguishing feature between HCV and HBV infection is that the latter forms a persistent mini-chromosome and it integrates into the host genome, whereas HCV is localised solely to the cytoplasmic compartment. Our current HBV antiviral drugs are highly effective in suppressing viral replication, but they cannot cure the infection that is present in >2 billion people worldwide.2 The immune system of most of these people is capable of effectively controlling the acute phase of HBV infection. However, a proportion of people with HBV infection have persistent viral replication and chronic inflammation that predisposes them to cirrhosis and hepatocellular carcinoma (HCC).

A vaccine has been available since the early 1980s that is highly effective in preventing HBV infection, but it has no therapeutic efficacy for the 360 million people who are chronically infected with HBV and have persistent disease.2 The replicative episomal form of HBV DNA, called covalently closed circular (ccc) DNA, prevents current therapies, including antiviral drugs, from being curative. These drugs need to be taken indefinitely to prevent viral relapse.3

Strengthened by the advent of HCV curative treatments, there is a huge interest in developing curative therapies for HBV infection. Potential new therapies for chronic hepatitis B include direct-acting antivirals, such as viral assembly inhibitors, gene silencing approaches and viral entry inhibitors.3 All of these therapies primarily target the virus itself and indeed many, if not most of our anti-infective agents rely on interfering with microbial proteins or the microbial genome to interrupt the ability of the pathogens to replicate.

A less explored avenue for the treatment of chronic infections, which may offer enormous potential, is targeting host cell factors that modulate cell signalling, innate or adaptive immune responses. Interferon therapy is an established method of modulating host responses to HBV infection and toll-like receptor agonists (e.g., TLR7 agonist) are currently being tested.3 However, to date none of these treatments have shown great efficacy in curing HBV infection.
TNF signalling and HBV infection

    Hepatitis B infection and current therapies • TNF signalling and HBV infection • HBV and IAPs – a vulnerable liaison • References • Author information

Recently, we developed a completely novel approach of inducing death of HBV-infected hepatocytes to eliminate the viral reservoir and cure infection in a small animal model.4,5 If this success translates to efficacy in clinical trials, infection can be eliminated along with the nidus for HCC development. Such a therapeutic intervention to combat chronic HBV infection has not been explored before. We discovered that gene-targeted mice lacking specific cellular IAPs (c-IAP1 and c-IAP2) were able to quickly and efficiently eliminate HBV-infected cells without causing overt collateral damage.4

IAPs are central critical regulators of a large number of cell-signalling pathways involved in the immune response, but also in regulating survival and cell death signalling downstream of death receptors. Our discoveries, potentially, had immediate therapeutic implications because IAP antagonists were already in clinical trials for the treatment of cancers. Birinapant is an example of an IAP antagonist currently being investigated in cancer clinical trials. We found that it effectively antagonised IAPs in hepatocytes and it promoted TNF-dependent elimination of HBV and cured infection in preclinical models.5

HBV is considered a non-cytopathic virus and it may utilise diverse mechanisms to abrogate TNF-mediated antiviral responses to infection. Indeed, TNF siganling is hijacked by HBV to enhance NF-κB transcriptional activity, and promote cell survival and activation to facilitate viral replication.6,7 In contrast, other studies have suggested that TNF may abrogate HBV replication by deregulating hepatocyte nuclear factors.8 Recent work implicated a role for TNF and IFNgamma, produced by T cells, in promoting non-cytolytic control of chronic HBV infection by diminishing the pool of cccDNA.9

TNF-mediated cell survival signalling is tightly regulated by IAPs, which function as ubiquitin E3 ligases via their RING domain.10 We observed no marked changes in c-IAP1 and XIAP levels in the liver during the first weeks after induction of HBV infection in our animal studies.4 Assessment of mouse c-IAP2 protein levels was not possible in these studies as there was no reliable antibody against this protein. Regardless of whether the levels of IAPs change during HBV infection, we found that c-IAP1 and c-IAP2 prevent the clearance of HBV infection.4 The therapeutic implications of this discovery were immediately tangible because IAP antagonists were already in clinical trials for other indications.

These drugs mimic the activity of an endogenous inhibitor of IAP function called Smac/Diablo. The small-molecule compounds called Smac mimetics were designed to mimic the inhibition of IAPs, antagonise their function and induce TNF-dependent cell death.11 Multiple clinical cancer trials validated the therapeutic applicability of Smac mimetics to induce targeted TNF-mediated death of tumour cells.
HBV and IAPs – a vulnerable liaison

    Hepatitis B infection and current therapies • TNF signalling and HBV infection • HBV and IAPs – a vulnerable liaison • References • Author information

In a completely novel approach, we used the Smac mimetic birinapant to reroute the signalling activity of endogenous TNF away from NF-κB activation and towards cell death induction in HBV-infected hepatocytes. We exploited the vulnerability created by HBV – a dependence on TNF/NF-κB and we harnessed the activity of endogenous TNF to kill cells in the absence IAPs. In our immunocompetent mouse model of chronic HBV infection, the Smac mimetic birinapant promoted TNF-mediated apoptosis of infected hepatocytes. Moreover, our study showed that birinapant preferentially killed infected cells over uninfected cells due to the vulnerability created by the virus.5 In addition, the ability of the immune system to localise production of TNF at the site of infection may mitigate collateral damage.

Our Smac mimetic therapeutic approach takes advantage of an Achilles heel in HBV’s attempt to utilise TNF to promote host cell survival and NF-κB activity. HBV X protein was shown to upregulate TNF expression.4,6 TNF and other pro-inflammatory cytokines in turn increase stability of the HBV X protein and they increase NF-κB signalling, which is essential for HBV replication.7 But the molecular details and mechanism of how HBV replication affects cell signalling and regulates induction of apoptosis or necroptosis warrant further investigations.

Another virus that has hijacked NF-κB signalling is HIV. In this case too much or too little NF-κB activity can cause problems for the host. HIV requires NF-κB for viral replication, but in the absence of sufficient. NF-κB activity HIV can adopt a quiescent latent integrated form. Latently infected cells are a dormant viral reservoir of HIV that can reseed the viral pool as soon as conventional antiviral therapy is stopped, thus preventing HIV cure. If all latently infected cells could be reactivated and killed, then the viral reservoir could be eliminated. It was recently shown that Smac mimetic-mediated depletion of c-IAP1, which is also a repressor of non-canonical NF-κB signalling, could activate transcriptional activity and reverse HIV-1 latency.12 We would speculate that additionally Smac mimetics could promote killing of the reactivated HIV-infected cells.

Our work demonstrated that we are able to beat the HBV virus at its own game. In a completely novel approach, we were able to promote TNF-mediated apoptosis of HBV-infected cells by taking advantage of the viruses addiction to TNF.5

Affiliations

    Division of Infection and Immunity, The Walter and Eliza Hall Institute of Medical Research, Parkville, Victoria , Australia
        G Ebert  & M Pellegrini
    Department of Medical Biology, The University of Melbourne, Parkville, Victoria , Australia
        G Ebert  & M Pellegrini

Competing interests

The Walter and Eliza Hall Institute of Medical Research has a research license agreement with TetraLogic Pharmaceuticals Corporation, Inc., the manufacturer of the cellular inhibitor of apoptosis protein antagonist birinapant. TetraLogic Pharmaceuticals Corporation, Inc., has filed a patent cooperation treaty application on behalf of The Walter and Eliza Hall Institute of Medical Research. MP provides consultative advice to TetraLogic Pharmaceuticals Corporation. GE owns stock in the company.

StephenW

细胞死亡发现|编辑打开

  
乙肝病毒和细胞凋亡抑制蛋白 - 一个弱势联络

    摹艾伯特＆M佩莱格里尼

      细胞死亡发现2，商品编号：16014（2016）DOI：10.1038 / cddiscovery.2016.14

网上公布
    2016年2月22日


主题词：

    •凋亡的细胞死亡和免疫反应•乙肝•目标识别•转化研究

乙型肝炎病毒感染和当前疗法

    乙型肝炎病毒感染和目前的治疗方法•TNF信令和HBV感染HBV•单边行动计划和 - 脆弱的联络•参考•作者信息

丙型肝炎病毒（HCV）感染的治疗已引入高度有效的抗病毒药物，可以成功地治愈大多数patients.1 HCV和HBV感染之间的主要区别特征革命性的是，后者的形式的持久微型染色体和它整合入宿主基因组中，而丙型肝炎病毒完全是定位于细胞质隔室。我们目前的乙肝抗病毒药物抑制病毒复制非常有效，但它们不能治愈感染存在于> 2的十亿人worldwide.2的这些人大多是能够有效地控制乙肝病毒感染的急性期的免疫系统。然而，人与乙肝病毒感染的比例有他们易于发生肝硬化和肝细胞癌（HCC）持续性病毒复制和慢性炎症。

疫苗已自80年代初是预防HBV感染非常有效可用，但它有3.6亿人谁是慢性乙型肝炎病毒感染和有持续disease.2 HBV DNA的复制游离形式没有治疗功效，被称为共价闭合环状（CCC）DNA，防止电流疗法，包括抗病毒药物，从被治愈。这些药物需要无限期地采取防止病毒relapse.3

由丙型肝炎病毒治疗疗效的到来加强，有必要制订疗效治疗HBV感染一个巨大的利益。治疗慢性乙型肝炎的潜在新疗法包括直接作用抗病毒剂，如病毒装配抑制剂，基因沉默的方法和病毒进入inhibitors.3所有这些疗法的主要目标病毒本身实际上许多，如果不是大多数的抗感染剂的依靠与微生物蛋白质或微生物基因组的干扰中断的病原体的复制能力。

一个不太探索途径用于治疗慢性感染，这可能提供了巨大的潜力，目标是能调节细胞信号传导，先天或获得性免疫反应宿主细胞因子。干扰素治疗是调节宿主对HBV感染与Toll样受体激动剂（例如，TL​​R7激动剂）目前正在tested.3然而，迄今为止没有这些治疗方法的建立的方法在治疗HBV感染已显示出巨大的功效。
TNF信令和HBV感染

    乙型肝炎病毒感染和目前的治疗方法•TNF信令和HBV感染HBV•单边行动计划和 - 脆弱的联络•参考•作者信息

最近，我们开发了一种完全新颖的诱导乙型肝炎病毒感染的肝细胞的死亡以消除病毒储在小动物model.4,5治愈感染如果这成功转化为在临床试验中的功效的方法中，感染可以沿与所消除的病灶肝癌发展。这样，打击慢性HBV感染的治疗干预之前没有探讨。我们发现，基因靶向的小鼠缺乏特异性细胞的IAP（C-IAP1和C-IAP2）能够迅速和有效地消除HBV感染的细胞，而不会引起明显的侧支damage.4

IAP的大量参与免疫应答的细胞信号传导途径的中央临界调节剂，而且在调节存活和细胞死亡信号死亡受体的下游。我们发现，潜在的，有直接的治疗意义，因为IAP拮抗剂用于癌症治疗的临床试验已经。 Birinapant是在癌症的临床试验目前正在研究的IAP拮抗剂的例子。我们发现，它有效地在肝细胞中拮抗的IAP和它促进HBV依赖于TNF的消除和固化感染在临床前models.5

乙肝病毒被认为是一种非细胞病变的病毒，它可利用多种机制来废除感染TNF介导的抗病毒反应。事实上，肿瘤坏死因子siganling由HBV劫持提升NF-κB的转录活性，并促进细胞的存活和活化，以促进病毒replication.6,7相比之下，其他的研究表明，TNF可以通过限制解除肝细胞核factors.8废除HBV复制最近的工作牵连TNF和的IFNγ的作用，由T细胞产生，促进慢性HBV感染的非溶细胞控制通过减少cccDNA.9池

TNF介导的细胞存活信令由单边行动计划，该功能会通过自己的戒指作为泛素E3连接酶domain.10我们在HBV感染诱导后的第一个星期内观察到肝脏C-IAP1和XIAP水平没有明显变化严格的调控我们鼠标C-IAP2蛋白水平的动物studies.4评估是不可能在这些研究中，因为在这样的蛋白质就没有可靠的抗体。不管乙肝病毒感染过程中的IAP变化的水平，我们发现，C-IAP1和c-IAP2防止乙肝病毒的清除infection.4这一发现的治疗意义，立即有形的，因为IAP拮抗剂用于其他适应症的临床试验已经。

这些药物模仿IAP功能的内源抑制剂称作的Smac / DIABLO的活性。称为Smac模拟物，小分子化合物被设计成模拟的IAP的抑制，拮抗它们的功能和诱导的TNF依赖性细胞death.11多个临床癌症试验验证Smac模拟物的治疗适用性诱导肿瘤细胞的靶向TNF介导的死亡。
HBV和单边行动计划 - 一个弱势联络

    乙型肝炎病毒感染和目前的治疗方法•TNF信令和HBV感染HBV•单边行动计划和 - 脆弱的联络•参考•作者信息

在一个完全新的方法中，我们使用的Smac模拟物birinapant从NF-κB活化和朝向细胞死亡诱导在HBV感染的肝细胞重新路由内源性的TNF的信号传导活性的路程。我们利用通过HBV产生的漏洞 - 对TNF / NF-κB的依赖，以及我们驾驭内源性TNF的活性杀死在没有单边行动计划的细胞。在我们的慢性HBV感染的免疫小鼠模型中，Smac的模拟birinapant促进感染的肝细胞肿瘤坏死因子介导的细胞凋亡。此外，我们的研究表明，birinapant优先杀死了未感染细胞的感染的细胞由于由virus.5另外创建的脆弱性，免疫系统的本地化TNF产生在感染部位的能力可能减轻附带损害。

我们的Smac模拟物的治疗方法乙肝病毒试图利用肿瘤坏死因子促进宿主细胞的存活和NF-κB活性需要一个致命弱点的优势。 HBV X蛋白显示出上调TNF expression.4,6 TNF和其它促炎性细胞因子在HBV X蛋白的转增加的稳定性和它们增加的NF-κB信号传导，这是乙型肝炎病毒replication.7但分子细节和基本乙肝病毒复制如何影响细胞信号和调节细胞凋亡或坏死的权证进一步调查的诱导机制。

已经劫持NF-κB信号的另一个病毒是HIV。在这种情况下，过多或过少的NF-κB活性可引起对主机的问题。 HIV需要NF-κB的病毒复制，但在没有充分的。 NF-κB活性的HIV可以采用静态潜集成形式。潜伏感染细胞是HIV的病毒处于休眠状态水库为传统的抗病毒治疗被停止，从而阻止HIV治疗，可以尽快补种病毒库。如果所有的潜伏感染细胞可以被重新激活和杀害，然后将病毒水库可能被淘汰。据最近显示的c-IAP1，这也是非经典的NF-κB信号传导的抑制，的Smac的模拟物介导的耗尽可以激活转录活性和反向的HIV-1 latency.12我们将推测另外Smac模拟物能促进在激活HIV感染细胞的杀伤。

我们的工作表明，我们有能力在自己的游戏中击败了乙肝病毒。在一个完全新颖的方法，我们能够通过利用病毒成瘾优势TNF.5促进HBV感染的细胞的TNF-α介导的凋亡

隶属关系

    感染与免疫，医学研究的沃尔特伊丽莎堂研究院，帕克维尔，维多利亚，澳大利亚的科
        摹艾伯特＆M佩莱格里尼
    医学生物学系，墨尔本，帕克维尔，澳大利亚维多利亚大学
        摹艾伯特＆M佩莱格里尼

利益冲突

医学研究的沃尔特伊丽莎堂研究院与TetraLogic制药公司，公司，凋亡抑制蛋白拮抗剂birinapant的细胞抑制剂的制造商的研究许可协议。 TetraLogic制药公司，公司已代医学研究的沃尔特伊丽莎厅研究所提出了专利合作条约申请。 MP提供TetraLogic制药公司的协商意见。 GE拥有股票的公司。

重韧

这个。是今 年在印度重启。还是明年来的。

hao2014

这个我就觉得奇怪

既然有副作用，一期为什么没查出来？？

而且当初做抗癌药的时候，做到二期，后面也没声音了，差不多四五年了吧

StephenW

重韧 发表于 2016-8-25 10:00
这个。是今 年在印度重启。还是明年来的。

Tetralogic没有消息，可能性非常低

StephenW

hao2014 发表于 2016-8-25 15:13
这个我就觉得奇怪

既然有副作用，一期为什么没查出来？？

做抗癌药的时候, 已经知道有副作用. 有预防措施.

抗癌临床试验继续.