氧化苦参碱在鸭原代肝细胞中抗鸭乙肝病毒(DHBV)作用的研究

通过建立鸭原代肝细胞-DHBV感染模型研究氧化苦参碱抗DHBV的作用。分别在DHBV感染前、感染同时以及感染后给药,利用打点杂交、Southern印迹核酸杂交和荧光定量PCR方法分别检测培养细胞上清及细胞内病毒核酸,观察氧化苦参碱在病毒感染的各个环节所起的抗病毒作用。实验结果显示:1mg/mL氧化苦参碱处理细胞后,鸭原代肝细胞培养上清及细胞内的DHBV核酸明显低于病毒感染对照组,病毒抑制率达91.6%;在病毒感染同时加药对病毒的抑制率可达98.5%;感染后持续用药能使不同培养天数的鸭肝细胞内的DHBV核酸降低60.5%~96.6%;氧化苦参碱与DHBV共孵育后,可以使病毒感染力下降69.6%。结果说明氧化苦参碱可以在DHBV感染鸭原代肝细胞的多个环节,包括病毒吸附、进入细胞及细胞内复制等方面发挥抗病毒作用。     

不同种雏鸭建立鸭乙肝病毒感染模型及抗病毒效果的实验

目的探讨不同种雏鸭建立鸭乙肝病毒感染模型的影响因素,观察应用该模型抗病毒的效果。方法采集鸭血清,应用PCR方法定性检测鸭血清中病毒DNA;定量PCR方法检测鸭血清中病毒DNA载量变化;用抗病毒药物处理,观察其在鸭DHBV感染模型中的抗病毒效果。结果不同种鸭DHBV自然感染率不同,樱桃谷鸭为8.75%,湖北麻鸭两个批次分别为17.80%和10.68%;静脉注射和腹腔注射两途径均能致雏鸭感染DHBV,静脉注射感染率80%,腹腔注射感染率65%;鸭感染DHBV后,体内病毒载量维持在106～108copies/mL,可持续20 d以上;抗病毒药物处理后,在不同DHBV模型中其抗病毒效果变化趋势一致。结论鸭的种类和人工感染途径可影响DHBV感染率;雏鸭感染DHBV后其体内有持续性的病毒血症;DHBV感染模型是药物抗病毒研究较好模型。     

鸭乙型肝炎病毒实验感染后在外周血和肝脏中的动态

鸭乙型肝炎病毒(DHBV)与人乙型肝炎病毒(HBV)同属嗜肝病毒,两者的病毒大分子结构和复制过程有很多相似之处,了解DHBV实验感染规律和病毒在血液和肝脏内的动态,有助于研究病毒复制特点和抗肝炎药物的效果。 本文用DHBV-DNA杂交阳性和DHBV-DNA多聚酶阳性的上海鸭血清,静脉注射1～3     

广东麻鸭DHBV全基因克隆及新读码框的发现

选取3份DHBV阳性广东麻鸭血清提取DHBV DNA,设计一对扩增DHBV全基因序列引物Q1和Q2,扩增并克隆DHBV全基因序列,测序并运用相关计算机软件及方法分析获得的全基因序列.结果表明,广东麻鸭DH-BV全长为3027bp.提交GenBank后获得的收录号分别为AY433937、AY521226、AY521227(来自1号血清);AY392760、AY536371(分别来自2、3号血清).AY521227的PreS/S ORF出现了单碱基突变,在PreC/CORF之前发现一个新的ORF,暂命名为HORF,HORF也同时存在于GenBank中储存的另外8个DHBV全基因序列中.系统发育分析表明,广东麻鸭DHBV在分化程度上是目前储存于GenBank中的DHBV全序列中最高的.成功克隆了广东麻鸭DHBV全基因序列,序列分析为进一步研究广东麻鸭DHBV提供了有益的信息.     

湖北麻鸭乙型肝炎病毒全基因组的克隆和序列分析

为了解湖北地区This finding was also Confirmed by the phylogenetic tree analysis.麻鸭中鸭乙型肝炎病毒(Duck hepatitis B virus,DHBV)自然感染状况以及湖北麻鸭所携带DHBV的基因结构特征,采集了70份成年麻鸭血清并应用PCR技术检测DHBV DNA,对其中一份DHBV DNA阳性血清进行DHBV全基因扩增,并进行克隆与序列测定分析.结果表明,湖北麻鸭DHBV自然携带率为10%;湖北DHBV分离株(GenBank登录号DQ276978)基因组的全长为3024bp,有编码P,S和C蛋白的三个开放阅读框;与GenBank中17株DHBV基因组比较,核苷酸同源性介于89.85%～93.29%之间;S蛋白、C蛋白和P蛋白结构功能区序列均高度保守;而对P蛋白标志性氨基酸和全基因进化树的分析表明,该分离株属于DHBV中国基因型中的一个亚型.     

鸭呼肠孤病毒强毒株致鸭胚原代成纤维细胞凋亡的研究

通过光镜、电镜、DNA Ladder法、流式细胞术、荧光染色对鸭呼肠孤病毒(DRV)诱导鸭胚原代成纤维细胞(DEF)凋亡情况进行检测.结果显示,光镜可见细胞形态学上出现细胞皱缩,染色质浓染边移;电镜观察到细胞胞浆浓缩,细胞核染色质凝聚、部分形成凋亡小体;荧光染色结果显示,在感染后24h有激发绿色荧光的凋亡细胞出现,随着时间的推移,激发红色荧光的死亡细胞数量增多;DNA Ladder检测到感染后24～144h的DNA样品呈梯形条带;流式细胞术于感染后24h检测到凋亡细胞,其数量在72～96h达到高峰,144h开始下降.研究结果表明,DRV在DEF增殖的过程中具有诱导宿主细胞凋亡的作用.     

湖北麻鸭乙型肝炎病毒全基因组的克隆和序列分析

为了解湖北地区Thisfindingwasalsoconfirmedbythephylogenetictreeanalysis.麻鸭中鸭乙型肝炎病毒(DuckhepatitisBvirus,DHBV)自然感染状况以及湖北麻鸭所携带DHBV的基因结构特征,采集了70份成年麻鸭血清并应用PCR技术检测DHBVDNA,对其中一份DHBVDNA阳性血清进行DHBV全基因扩增,并进行克隆与序列测定分析。结果表明,湖北麻鸭DHBV自然携带率为10%;湖北DHBV分离株(GenBank登录号DQ276978)基因组的全长为3024bp,有编码P,S和C蛋白的三个开放阅读框;与GenBank中17株DHBV基因组比较,核苷酸同源性介于89.85%~93.29%之间;S蛋白、C蛋白和P蛋白结构功能区序列均高度保守;而对P蛋白标志性氨基酸和全基因进化树的分析表明,该分离株属于DHBV中国基因型中的一个亚型。     

广东麻鸭DHBV全基因克隆及新读码框的发现

选取3份DHBV阳性广东麻鸭血清提取DHBVDNA,设计一对扩增DHBV全基因序列引物Q1和Q2,扩增并克隆DHBV全基因序列,测序并运用相关计算机软件及方法分析获得的全基因序列。结果表明,广东麻鸭DH-BV全长为3027bp。提交GenBank后获得的收录号分别为:AY433937、AY521226、AY521227(来自1号血清);AY392760、AY536371(分别来自2、3号血清)。AY521227的PreS/SORF出现了单碱基突变,在PreC/CORF之前发现一个新的ORF,暂命名为HORF,HORF也同时存在于GenBank中储存的另外8个DHBV全基因序列中。系统发育分析表明,广东麻鸭DHBV在分化程度上是目前储存于GenBank中的DHBV全序列中最高的。成功克隆了广东麻鸭DHBV全基因序列,序列分析为进一步研究广东麻鸭DHBV提供了有益的信息。     

中国安徽庐江鸭乙型肝炎病毒全基因组克隆酶谱分析和部分病毒基因正负单链探针的构建

用鸭乙型肝炎病毒(DHBV)阳性的安徽庐江鸭血清感染DHBV阴性的北京雏鸭,扩增病毒,将提取的DHBV-DNA插入pUC18质粒,转化E.coli JM 105。酶切重组质粒及South-ern转膜杂交结果证实,质粒pLJ76的插入片段为DHBV全基因组。用EcoR Ⅰ等11种限制性内切酶对pLJ76进行酶谱分析,并与美国,西德的已知DHBV基因组比较。定向克隆该株病毒不同基因编码区片段,构建正负单链探针,将斑点杂交和单链电泳检出的M13阳性重组子与已知序列的DHBV基因组作比较,提示获得了该株病毒基因组的S、Pre-S、P和X/C等蛋白编码区的正、负单链克隆株。     

鸭胚胎干细胞分离与鉴定

采用药勺法分离仙湖3号肉鸭鸭胚的胚盘细胞,并以鸭胚成纤维细胞作为饲养层,培养鸭胚胎干细胞。在此基础上,通过对体外培养的鸭胚胎干细胞形态观察,碱性磷酸酶染色(AKP)以及胚胎阶段表面特异性抗原(SSEA-1)免疫组化等方法,分离与鉴定鸭胚胎干细胞。结果表明传至第3代的鸭胚胎干细胞经AKP和SSEA-1鉴定均为阳性,AKP染色为深蓝色,SSEA-1染色呈绿色荧光,表明培养至第3代的鸭胚胎干细胞仍保持干细胞未分化特性,具有胚胎干细胞的特征。结果提示本试验分离、培养的鸭胚盘细胞为鸭胚胎干细胞。     

Production of infectious duck hepatitis B virus in a human hepatoma cell line.

The differentiated human hepatoma cell line Hep-G2 was transfected with cloned duck hepatitis B virus (DHBV) DNA. Introduction of closed circular DNA into the human liver cells resulted in the production of viral proteins: core antigen was detected in the cytoplasm, and e antigen, a related product, was secreted into the medium. Moreover, viral particles were released into the tissue culture medium which were indistinguishable from authentic DHBV by density, antigenicity, DNA polymerase activity, and morphology. Intravenous injection of tissue culture-derived DHBV particles into Pekin ducks established DHBV infection. In conclusion, transfection of human hepatoma cells with cloned DHBV DNA results in the production of infectious virus, as occurs with cloned human hepatitis B virus DNA. Human liver cells are therefore competent to support production of the avian and mammalian hepadnaviruses, indicating that liver-specific viral gene expression is controlled by evolutionarily conserved mechanisms. This new DHBV transfection system offers the opportunity to rapidly produce mutated DHBV which then can be further investigated in Pekin ducks.     

Glycine decarboxylase mediates a postbinding step in duck hepatitis B virus infection

Envelope protein precursors of many viruses are processed by a basic endopeptidase to generate two molecules, one for receptor binding and the other for membrane fusion. Such a cleavage event has not been demonstrated for the hepatitis B virus family. Two binding partners for duck hepatitis B virus (DHBV) pre-S envelope protein have been identified. Duck carboxypeptidase D (DCPD) interacts with the full-length pre-S protein and is the DHBV docking receptor, while duck glycine decarboxylase (DGD) has the potential to bind several deletion constructs of the pre-S protein in vitro. Interestingly, DGD but not DCPD expression was diminished following prolonged culture of primary duck hepatocytes (PDH), which impaired productive DHBV infection. Introduction of exogenous DGD promoted formation of protein-free viral genome, suggesting restoration of several early events in viral life cycle. Conversely, blocking DGD expression in fresh PDH by antisense RNA abolished DHBV infection. Moreover, addition of DGD antibodies soon after virus binding reduced endogenous DGD protein levels and impaired production of covalently closed circular DNA, the template for DHBV gene expression and genome replication. Our findings implicate this second pre-S binding protein as a critical cellular factor for productive DHBV infection. We hypothesize that DCPD, a molecule cycling between the cell surface and the trans-Golgi network, targets DHBV particles to the secretary pathway for proteolytic cleavage of viral envelope protein. DGD represents the functional equivalent of other virus receptors in its interaction with processed viral particles.     

Covalently closed circular DNA is the predominant form of duck hepatitis B virus DNA that persists following transient infection

Residual hepatitis B virus (HBV) DNA can be detected in serum and liver after apparent recovery from transient infection. However, it is not known if this residual HBV DNA represents ongoing viral replication and antigen expression. In the current study, ducks inoculated with duck hepatitis B virus (DHBV) were monitored for residual DHBV DNA following recovery from transient infection until 9 months postinoculation (p.i.). Resolution of DHBV infection occurred in 13 out of 15 ducks by 1-month p.i., defined as clearance of DHBV surface antigen-positive hepatocytes from the liver and development of anti-DHBV surface antibodies. At 9 months p.i., residual DHBV DNA was detected using nested PCR in 10/11 liver, 7/11 spleen, 2/11 kidney, 1/11 heart, and 1/11 adrenal samples. Residual DHBV DNA was not detected in serum or peripheral blood mononuclear cells. Within the liver, levels of residual DHBV DNA were 0.0024 to 0.016 copies per cell, 40 to 80% of which were identified as covalently closed circular viral DNA by quantitative PCR assay. This result, which was confirmed by Southern blot hybridization, is consistent with suppressed viral replication or inactive infection. Samples of liver and spleen cells from recovered animals did not transmit DHBV infection when inoculated into 1- to 2-day-old ducklings, and immunosuppressive treatment of ducks with cyclosporine and dexamethasone for 4 weeks did not alter levels of residual DHBV DNA in the liver. These findings further characterize a second form of hepadnavirus persistence in a suppressed or inactive state, quite distinct from the classical chronic carrier state.     

In vitro experimental infection of primary duck hepatocyte cultures with duck hepatitis B virus.

Duck hepatitis B virus (DHBV) obtained from the serum of congenitally infected ducks was used to infect primary duck hepatocyte cultures 1 to 4 days after plating. Virus replication was demonstrated by the appearance, beginning at 2 days after infection, of intracellular covalently closed-circular and single-stranded DHBV DNA replicative intermediates which were not present in the inoculating virus preparation. With increasing time after infection there was further amplification of intracellular relaxed circular, covalently closed-circular, and single-stranded DHBV DNA. Cultures of primary duck hepatocytes are competent for infection with DHBV only during the first 4 days of culture. Synthesis of DHBV core antigen and DHBV surface antigen was detected by immunofluorescence in 10% of the hepatocytes in culture. De novo synthesis and release of infectious virus was also demonstrated. Therefore, all stages of viral replication were carried out by these experimentally infected primary hepatocyte cultures. This system makes it possible to study DHBV replication in vitro.     

Susceptibility to duck hepatitis B virus infection is associated with the presence of cell surface receptor sites that efficiently bind viral particles.

To test the hypothesis that susceptibility of hepatocytes to duck hepatitis B virus (DHBV) infection requires cell surface receptors that bind the virus in a specific manner, we developed an assay for the binding of DHBV particles to monolayers of intact cells, using radiolabeled immunoglobulin G specific for DHBV envelope protein. Both noninfectious DHBV surface antigen particles and infectious virions bound to a susceptible fraction (approximately 60%) of Pekin duck hepatocytes. In contrast, binding did not occur to cells that were not susceptible to DHBV infection, including Pekin duck fibroblasts and chicken hepatocytes, and binding to Muscovy duck hepatocytes, which are only weakly susceptible (approximately 1% of cells) to DHBV infection, was virtually undetectable. Within a monolayer, individual Pekin duck hepatocytes appeared to differ markedly in the capacity to bind DHBV, which may explain difficulties that have been encountered in infecting 100% of cells in culture. We have also found that the loss of susceptibility to infection with DHBV that occurs when Pekin duck hepatocytes are maintained for more than a few days in culture correlates with a decline in the number of cells that bind virus particles efficiently. All of these results support the interpretation that the binding event detected by our assay is associated with the interaction between DHBV and specific cell surface receptors that are required for initiation of infection. Our assay may facilitate isolation and identification of hepatocyte receptors for this virus.     

Carboxypeptidase D Is an Avian Hepatitis B Virus Receptor

The receptor molecules for human and animal hepatitis B viruses have not been defined. Previous studies have described a 170 to 180 kDa molecule (p170 or gp180) that binds in vitro to the pre-S domain of the large envelope protein of duck hepatitis B virus (DHBV); cDNA cloning revealed the binding protein to be duck carboxypeptidase D (DCPD). In the present study, the DCPD cDNA was transfected into several nonpermissive human-, monkey-, and avian species-derived cell lines. Cells transfected with a plasmid encoding the full-length DCPD protein bound DHBV particles, whereas cells expressing truncated versions of DCPD protein that fail to bind the pre-S protein did not. The DHBV binding to DCPD-reconstituted cells was blocked by a monoclonal antibody that neutralizes DHBV infection of primary duck hepatocytes (PDH) and also by a pre-S peptide previously shown to inhibit DHBV infection of PDH. In addition to promoting virus binding, DCPD expression was associated with internalization of viral particles. The entry process was prevented by incubation of reconstituted cells with DHBV at 4 degrees C and by the addition of energy-depleting agents known to block DHBV entry into PDH. These results demonstrated that DCPD is a DHBV receptor. However, the lack of complete viral replication in DCPD-reconstituted cells suggested that additional factors are required for postentry events in immortalized cell lines.