基于滚环扩增的鸭乙型肝炎病毒共价闭合环状DNA检测方法的建立

滚环扩增(RCA)是新近发展起来的一种能特异性扩增环形DNA的实验技术,自2008年以来被广泛用于HBV基因全长扩增及共价闭合环状DNA(cccDNA)耐药突变分析等研究。为了便于鸭乙型肝炎病毒(DHBV)cccDNA的分析,本研究建立了基于RCA的DHBV cccDNA的检测方法。通过针对DHBV高度保守序列设计的4对RCA硫化修饰引物,以血清DHBV DNA为阴性对照,从肝组织DHBV DNA标本中扩增得到DHBV cccDNA。然后用跨缺口引物扩增RCA产物测序替代限制性内切酶切分析进行DHBV cccDNA鉴定。应用该方法检测39份携带DHBV麻鸭肝组织与血清标本结果显示:全部肝组织标本均检出DHBV cccDNA,而全部血清标本则均无DHBV cccDNA检出,表明本研究建立的基于RCA的DHBV cccDNA检测法具有良好的特异性和灵敏性。该方法的建立为应用鸭乙型肝炎病毒动物模型研究cccDNA在病毒致病机制中的作用以及评价抗病毒疗效奠定了实验基础。     

利用乙型肝炎病毒共价闭合环状DNA构建慢性乙型肝炎病毒感染的小鼠模型

目的通过水动力法注射乙型肝炎病毒(HBV)共价闭合环状DNA(cccDNA)构建C57BL/6小鼠慢性乙型肝炎病毒感染的模型。方法取29只C57BL/6小鼠,分为实验组、对照组和空白组,应用水动力法分别注射HBV cccDNA、pAAV-HBV1.2及等渗盐水,于注射后收集不同时间点的血清和肝组织。利用放射免疫法检测血清样本中乙型肝炎病毒表面抗原(HBsAg)和乙型肝炎病毒e抗原(HBeAg);荧光定量PCR检测血清和肝组织中HBV DNA拷贝数;免疫组织化学法检测肝组织中HBsAg和乙型肝炎病毒核心抗原(HBc Ag)的表达;苏木精-伊红(HE)染色观察肝组织病理变化;使用SPSS 17.0对数据进行统计学分析。结果实验组HBsAg和HBeAg表达均呈现4个上升-下降曲线:HBsAg峰值分别出现在第3天、第3周、第7周和第9周;HBeAg峰值分别出现在第1天、第1周、第4周和第10周。对照组HBsAg和HBeAg表达分别呈现2个或3个明显的峰:HBsAg峰值分别出现在第3天和第8周;HBeAg峰值分别出现在第1天、第3周和第10周。空白组未检测出HBsAg和HBeAg。实验组HBV DNA拷贝数高于对照组的拷贝数(P<0.01);肝组织中HBV DNA拷贝数高于同期血清中的拷贝数(P<0.01);实验组和对照组的肝组织中均有HBsAg和HBc Ag的表达;实验组与对照组出现肝脏细胞炎症、肝细胞纤维化、肝细胞坏死等病理变化,而空白组正常。结论利用水动力法向C57BL/6小鼠体内转入HBV cccDNA,成功建立了慢性乙型肝炎病毒感染的小鼠模型,与对照组比较,新建立的小鼠乙肝模型具有更高的HBV表达,动物模型为研究乙型肝炎病毒HBV cccDNA的感染及其引起肝损伤的机制奠定了基础。     

应用微环DNA技术体外诱导和制备重组的乙型肝炎病毒共价闭合环状DNA

乙型肝炎病毒(hepatitis B virus,HBV)共价闭合环状DNA(covalently closed circular DNA,cccDNA)是病毒慢性感染的分子基础。本课题组前期研究通过Cre/loxP介导的位点特异性DNA重组策略,在细胞核内由前体质粒诱导重组cccDNA(rcccDNA^loxP)产生,首次建立了HBV cccDNA的体外培养细胞和小鼠实验模型。本研究基于大肠埃希菌ZYCY10P3S2T PhiC31重组酶诱导表达系统,建立了一种体外诱导HBV rcccDNA(rcccDNA^attR)微环产生和纯化的策略。纯化的rcccDNA^attR微环具有超螺旋结构,细胞培养实验证实其能支持功能性的HBV复制和抗原表达。与普通的线性HBV复制子编码质粒相比,rcccDNA^attR尾静脉高压注射小鼠模型能诱导显著延长的病毒抗原血症。因此,本研究在原核表达系统和实验小鼠水平提供了一种更为简化的HBV cccDNA实验模型系统,并再次显示rcccDNA具有显著的稳定性,能作为一种基本策略在小鼠模型中诱导病毒持续感染。     

乙型肝炎病毒共价键闭环DNA的表观遗传调控研究进展

乙型肝炎病毒(hepatitis B virus,HBV)感染仍然是威胁全球人类生命与健康的重要危险因素。虽然目前的抗病毒治疗药物在控制乙型肝炎进展有显著疗效,但却始终无法达到根治HBV感染的目标。HBV共价闭合环状DNA(HBV cccDNA)是HBV转录复制的原始模板,也是HBV持续感染的关键因素。但由于缺少有效的完全清除HBV cccDNA的治疗方法,慢性乙型肝炎患者需长期服药以防治疗后停药复发。研究证实HBV cccDNA的转录受表观遗传机制调控,其中cccDNA甲基化、组蛋白修饰、miRNA、染色质重塑等均影响HBV cccDNA的功能。本文就HBV表观遗传调控的最新研究进展进行综述。     

乙型肝炎病毒核心蛋白变构调节剂的研究进展

由于乙型肝炎病毒(hepatitis B virus,HBV)的共价闭合环状DNA的持续存在和病毒介导的宿主免疫反应钝化,导致慢性乙型肝炎病毒感染很难治愈。现有的核苷(酸)类似物或聚乙二醇干扰素疗法难以实现高比率的HBV表面抗原清除。目前正在研发的核心蛋白变构调节剂有望大幅度降低血清表面抗原。本文就HBV核心蛋白的结构、功能以及核心蛋白变构调节剂的分类、应用前景等方面进行综述。     

一种简易的抽提共价闭合环状DNA的方法

纯净的、具有生物学活性的共价闭合环状DNA是DNA体外重组技术的一个重要基础。 本文报道的是我们实验室经常使用的抽提质粒pBR 322 DNA的方法。在Zasloff等酸酚法的基础上省略了蛋白酶K和RNA酶,代之     

CRL4在增殖的肝细胞系中上调乙型肝炎病毒抗原的分泌表达

乙型肝炎病毒（hepatitis B virus,HBV）编码的X蛋白（hepatitis B virus X protein,HBx）对HBV感染的起始和维持至关重要。HBx可能作为病毒来源的接头分子,介导Cullin-RING E3泛素连接酶4（cullin-RING ubiquitin E3 ligase 4,CRL4）复合物对染色体外DNA限制因子SMC5/6的降解。最近研究发现CRL4接头分子DNA损伤结合蛋白1（DNA damage-binding protein 1,DDB1）可不依赖与HBx的相互作用而直接上调病毒的表达和复制。本研究基于HBx基因删除（X-null）的HBV重组cccDNA（recombinant covalently closed circular DNA,rcccDNA）模型系统,在多种体外培养肝细胞系中证实上述发现。有意思的是,CRL4刺激rcccDNA^X-null转染细胞抗原分泌表达的效应能被血清饥饿实验抵消。应用尾静脉高压注射小鼠模型,同样发现CRL4并不上调rcccDNA^X-null在非增殖小鼠肝脏细胞中的表达。以上结果提示,细胞增殖特征与CRL4不依赖HBx上调病毒抗原表达的效应密切相关,有助于HBx生物学意义的准确分析和理解。     

新生隐球菌基因组DNA不同抽提方法的比较

目的 DNA是进行分子生物学研究的重要基础。在本研究中,我们建立了2种简单快速抽提基因组DNA的方法并可用作PCR扩增的模板。通过比较4种不同的DNA抽提方法以确定哪种更适合进行下一步的基因分析。方法这4种方法是:玻璃珠法,酶法,3%SDS法和氯化苄法。玻璃珠法是用玻璃珠在混漩器上剧烈振荡破碎细胞壁;3%SDS法是将细胞在含10mmol/LDTT的3%SDS溶液中加热,然后用5mmol/LKAc和异丙醇抽提,DNA的产量通过A260测定。结果 3%SDS溶解法、经典酶法、玻璃珠法和氯化苄法的DNA产量分别为0.4154±0.0367、0.8484±0.0756、1.2636±0.2040、0.4070±0.0339(g/L×108CFU/mL)。结论玻璃珠法是最敏感、重复性好、简单、费用合理的抽提方法 。     

一种简易的抽提共价闭合环状DNA的方法1)

纯净的、具有生物学活性的共价闭合环状 DNA是DNA体外重组技术的一个重要基础。     

一种改进的快速有效的裸藻DNA抽提方法

大多数裸藻为单细胞游动种类,无细胞壁,细胞质外层特化为表质,部分种类细胞具胶质的囊壳,表质、囊壳的主要成分为蛋白质,使之具有柔韧的类牛皮糖的特性,给裸藻破细胞、DNA抽提及进行下一步工作造成一定的难度,本文在比较、改进的基础上,得到一种快速有效的裸藻DNA抽提方法。       

Recent advances in the study of hepatitis B virus covalently closed circular DNA

Chronic hepatitis B infection is caused by hepatitis B virus (HBV) and a total cure is yet to be achieved. The viral covalently closed circular DNA (cccDNA) is the key to establish a persistent infection within hepatocytes. Current antiviral strategies have no effect on the pre-existing cccDNA reservoir. Therefore, the study of the molecular mechanism of cccDNA formation is becoming a major focus of HBV research. This review summarizes the current advances in cccDNA molecular biology and the latest studies on the elimination or inactivation of cccDNA, including three major areas: (1) epigenetic regulation of cccDNA by HBV X protein, (2) immune-mediated degradation, and (3) genome-editing nucleases. All these aspects provide clues on how to finally attain a cure for chronic hepatitis B infection.

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Concerted action of activation-induced cytidine deaminase and uracil-DNA glycosylase reduces covalently closed circular DNA of duck hepatitis B virus

Covalently closed circular DNA (cccDNA) forms a template for the replication of hepatitis B virus (HBV) and duck HBV (DHBV). Recent studies suggest that activation-induced cytidine deaminase (AID) functions in innate immunity, although its molecular mechanism of action remains unclear, particularly regarding HBV restriction. Here we demonstrated that overexpression of chicken AID caused hypermutation and reduction of DHBV cccDNA levels. Inhibition of uracil-DNA glycosylase (UNG) by UNG inhibitor protein (UGI) abolished AID-induced cccDNA reduction, suggesting that the AID/UNG pathway triggers the degradation of cccDNA via cytosine deamination and uracil excision.     

Formation of covalently closed circular DNA in Hep38.7-Tet cells,a tetracycline inducible hepatitis B virus expression cell line

Hepatitis B virus (HBV) covalently closed circular DNA (cccDNA) plays a central role in chronic HBV infection. However, analysis of the molecular mechanism of cccDNA formation is difficult because of the low efficiency in tissue cultured cells. In this study, we developed a more efficient cccDNA expression cell, Hep38.7-Tet, by subcloning from a tetracycline inducible HBV expression cell, HepAD38. Higher levels of cccDNA were produced in Hep38.7-Tet cells compared to HepAD38 cells. In Hep38.7-Tet cells, the cccDNA was detectable at six days after HBV induction. HBV e antigen (HBeAg) secretion was dependent upon cccDNA production. We screened chemical compounds using Hep38.7-Tet cells and HBeAg secretion as a marker. Most of the hit compounds have already been reported as anti-HBV compounds. These data suggested that Hep38.7-Tet cells will be powerful tools for analysis of the molecular mechanism of cccDNA formation/maintenance and development of novel therapeutic agents to control HBV infection.     

免疫因素及cccDNA 与HBV的持续感染

由于乙肝疫苗普遍接种,乙型肝炎的流行已经下降,但慢性乙型肝炎（CHB）仍是严重的全球性公共卫生问题。超螺旋共价闭合环状DNA（cccDNA）作为原始转录模板,逃避机体免疫及抗病毒药物清除,在HBV持续感染中发挥重要作用。基于调节患者对HBV的免疫功能研究新的治疗策略以清除细胞核内cccDNA可能成为根除HBV持续感染的途径。     

Advances in research on hepatitis B virus DNA integration

Since HBV DNA integration was discovered for the first time in 1980, various methods have been used to detect and study it, such as Southern Blot, in situ hybridization, polymerase chain reaction and so on. HBV DNA integration is thought to be random on the whole although some hot spots of integration were described by some researchers, one of which might be the repetitive sequences of the genomic DNA. Besides, DNA damage, especially double-strand breaks could promote HBV DNA integration into host genome. HBV DNA integration into cells may damage the stability of the genome, cause DNA rearrangement, promote DNA deletion and induce the formation of HCC.     

Interference of hepatitis B virus with cellular signaling

The presence of hepatitis B virus (HBV) proteins leads to changes in the cellular gene expression. As a consequence, the cellular signaling processes are influenced by the actions of HBV proteins. It has been shown that HBV nucleocapsid protein and the amino-terminal part of polymerase termed as terminal protein (TP) could inhibit interferon signaling. Further, the global gene expression profiles differ in hepatoma cells with and without HBV gene expression and replication. The expression of interferon (IFN) stimulated genes (ISGs) was differently regulated in cells with HBV replication and could be modulated by antiviral treatments. The HBV TP has been found to modulate the ISG expression and enhance the HBV replication. The modulation of the cellular signaling processes by HBV may have significant implications for pathogenesis.     

Modeling the mechanisms of acute hepatitis B virus infection

Mathematical models have been used to understand the factors that govern infectious disease progression in viral infections. Here we focus on hepatitis B virus (HBV) dynamics during the acute stages of the infection and analyze the immune mechanisms responsible for viral clearance. We start by presenting the basic model used to interpret HBV therapy studies conducted in chronically infected patients. We then introduce additional models to study acute infection where immune responses presumably play an important role in determining whether the infection will be cleared or become chronic. We add complexity incrementally and explain each step of the modeling process. Finally, we validate the model against experimental data to determine how well it represents the biological system and, consequently, how useful are its predictions. In particular, we find that a cell-mediated immune response plays an important role in controlling the virus after the peak in viral load.