C基因截短的HBV复制与包装

目的 探讨C基因截短型HBV变异体的复制与包装。方法 采用分子克隆、人工定点突变等技术构建C基因截短型HBV变异体质粒，用脂质体法转染HepG2细胞，提取细胞内及培养上清液中DNA分别进行Southem杂交，PCR及实时定量荧光PCR分析。结果 经DNA测序及酶切鉴定证实C基因截短型HBV质粒载体构建成功；C基因截短型HBV为复制缺损型，与辅助质粒共转染HepG2细胞，可在细胞内及培养上清液中检测到HBV各种DNA构型；DNA定量分析提示C基因截短型HBV的包装效率较野生型HBV提高3～40倍。结论 C基因截短型HBV变异体为复制缺损型，单独转染后不能在肝细胞内包装与复制，但在缺失包装信号ε的相应辅助病毒辅助下可有效复制并包装成子代病毒颗粒分泌到胞外，且包装效率大大提高。     

Enhanced core protein production by hepatitis B virus bearing a mutation in the precore region

Summary.  An HBV DNA tandem dimer bearing GTG instead of the precore initiation codon (p2WPC-), that bearing an amber mutation at precore codon 28 (p2WPCTer) and that of a wild-type were introduced into HepG2 cells. p2WPC- produced no HBeAg, the same amount of HBsAg as the wild-type, and 2–4 times as much HBcAg and progeny virus DNA. p2WPCTer produced no HBeAg, the same amount of HBsAg, 2 times as much HBcAg and a slightly increased amount of progeny virus. The amounts of p21^c peptide in both mutants determined by immunoblotting correlated well with the ELISA titers. These results suggest that these precore single point mutations are responsible for the enhanced core peptide production. Received August 12, 1996 Accepted December 13, 1996     

Hepatitis B virus harboring nucleotide deletions in the core promoter region and genotype B correlate with low viral replication activity in anti-HBe positive carriers.

BACKGROUND: Emergence of anti-HBe following seroconversion of HBe antigen indicates reduced hepatitis B virus (HBV) replication in the liver and low infectivity in the natural course of infection. However, some patients show continued replication or reactivation even in the presence of anti-HBe. OBJECTIVE: To clarify the cause of HBV replication, we investigated genotype differences and mutations in the core promoter and precore region in relation to virus titer. STUDY DESIGN: Using quantification of HBV DNA, nucleotide sequencing of the core promoter and precore region, and genotyping with the S gene by restriction fragment length polymorphism (RFLP), we analyzed sera of 26 anti-HBe positive carriers (28 serum samples). RESULTS: Various mutations were detected including C to T point mutation at nt 1653, A to T and G to A contiguous point mutations at nt 1762 and 1764 in the core promoter region, and G to A point mutation at nt 1896 in the precore region, but no common mutations were detected that were directly related to the virus titer from earlier reported mutations. In contrast, the mean titer of genotype B virus was 1.5 x 10(5) copies per ml and that of mutant HBV of genotype C having 8 base pairs (8-bp) deletion (nt 1768-1775) in the core promoter region was 7.9 x 10(4) copies per ml (mean titer). These titers showed commonly lower than that of genotype C virus without 8-bp deletion (median titer 5.0 x 10(6) copies per ml). Transition of genotype from C to B after viral reactivation and reduction of proportion of 8-bp deletion mutant at reactivation period was observed in a patient who demonstrated exacerbation of liver dysfunction due to immunosuppressive therapy and increased viral replication. CONCLUSIONS: These results confirm those of our earlier study describing low replication ability of 8-bp deletion mutant HBV in vitro, and also indicate that the presence of genotype B correlates with reduced titer of HBV.     

In vitro replication phenotype of a novel (-1G) hepatitis B virus variant associated with HIV co-infection

The -1G mutant HBV is more prevalent in individuals co-infected with HIV/HBV than in individuals infected with HBV alone and in some cases is the dominant virus in circulation. This mutant is created by the deletion of a dGMP (-1G) from the guanine rich homopolymer sequence located at nts 2,085-2,090 (numbering from EcoRI site as position 1) in the HBV core gene. This deletion causes a frameshift generating a premature stop codon at (64) Asn in the HBV core gene (codon 93 in the precore gene), that truncates the precore protein, precursor of the secreted hepatitis B "e" antigen (HBeAg), and the core protein which forms the viral nucleocapsid. However, the replication phenotype of the -1G mutant HBV is unknown. An in vitro cell culture model in which hepatoma cells were transiently transfected with infectious cDNAs was used to show that the -1G mutant HBV is incapable of autonomous replication and, as expected, replication was restored to wild-type (wt) levels by supplying HBV core protein in trans. Although the -1G mutation had no deleterious effect on intracellular HBV-DNA levels, high levels of -1G mutant HBV relative to wt HBV reduced virus secretion and HBeAg secretion relative to empty vector controls. Importantly, the -1G mutant HBV also caused intracellular retention of truncated precore protein in the endoplasmic reticulum (ER) and Golgi apparatus. Together, these effects may be contributing to the increased pathology observed in the setting of HIV/HBV co-infection.     

Effect of mutating the two cysteines required for HBe antigenicity on hepatitis B virus DNA replication and virion secretion

Hepatitis B virus (HBV) variants with impaired expression of e antigen (HBeAg) frequently arise at the chronic stage of infection, as exemplified by precore and core promoter mutants. Since an intramolecular disulfide bond maintains the secondary structure of HBeAg, we explored effect of missense mutations of either cysteine codon. Consistent with earlier reports, substitution of each cysteine rendered HBeAg nearly undetectable. With underlying nucleotide changes at the loop of pregenome encapsidation signal, the C-7 mutants were severely impaired in pregenomic RNA packaging and hence DNA replication. Although none of the missense mutations at C61 reduced DNA replication, replacement with arginine, but not alanine, aspartic acid, phenylalanine, or serine, blocked virion secretion. Consistent with the detection of C61R genome from a patient serum, secretion block of the C61R mutant could be overcome by co-expression of wild-type core protein. In conclusion, point mutations of the C61 codon may generate viable HBeAg-negative variants.     

HBc二聚体组装核衣壳相关功能域突变对HBV复制的影响

目的 探讨乙型肝炎病毒核心蛋白(hepatitis B virus core protein,HBc)二聚体组装相关功能域突变对核心颗粒组装及HBV复制的影响.方法 基于HBc空间结构,PCR定点诱变二聚体组装核衣壳相关功能域重要氨基酸位点,以pcDNA3.1为载体构建4个突变体表达质粒pHBc14-18M、pHBc120-135M、pHBc23-39M和pHBc122-139M.将突变质粒与HBc缺失的含1.2拷贝HBV基因质粒pHBV1.2-core-共转染HepG2细胞,通过Northern blot检测HBV前基因组(pgRNA),Southern blot检测复制中间体,非变性琼脂糖凝胶电泳(native agarose gel electrophoresis)及Western blot检测细胞核心颗粒观察突变质粒自身形成核衣壳情况.将突变质粒与含有1.2拷贝HBV基因质粒pHBV1.2共转染HepG2细胞观测突变质粒对野生型HBc组装及HBV复制的影响.结果 突变质粒与pHBV1.2-core-质粒共转染HepG2细胞,pHBc14-18M、pHBc120-135M和pHBc122-139M突变能够组成核衣壳样结构.pHBc23-39M不能形成核衣壳样结构.Northern blot结果显示所有突变质粒组均未见pgRNA条带,Southern blot检测复制中间体也未见条带.将突变质粒与pHBV1.2共转染HepG2细胞,pHBc14-18M、pHBc120-135M和pHBc122-139M组HBV复制中间体及上清中病毒颗粒明显减少,而pHBc23-39M组无减少.结论 HBc23-39位氨基酸突变可阻止二聚体多聚化,不能形成核衣壳样结构,且不能与野生HBc二聚体相互作用.HBc14-18、120-135、122-139区域的氨基酸突变,能够形成核衣壳样结构但不支持HBV DNA复制,并且能与野生HBc二聚体相互作用,形成杂合体,干扰野生型HBV DNA的复制.     

Evolution of viral load and changes of polymerase and precore/core promoter sequences in lamivudine-resistant hepatitis B virus during adefovir therapy

Adefovir dipivoxil (ADV) has demonstrated clinical activity against both wild-type and lamivudine-resistant hepatitis B virus (HBV). We analyzed the evolution of viral load and the changes of polymerase and precore/core promoter sequences in lamivudine-resistant virus during ADV therapy. The authors studied 14 patients who had breakthrough hepatitis after lamivudine therapy. Serial sera were obtained prior to adefovir administration and at 3, 6 and 12 months after ADV therapy. Nucleotide sequences of polymerase and the precore/core promoter from the hepatitis B virus were analyzed. The median serum HBV DNA decrease with adefovir treatment was 4.35 log(10) copies/mL at 12 months. Tyrosine-methionine-aspartate-aspartate (YMDD) mutants were found in 12 patients among the 14 patients with lamivudine resistance. The YMDD mutant viruses reversed to the wild-type in 6 patients out of the 12 patients after 3-6 months of ADV after discontinuing lamivudine therapy. In the analysis of the nucleotide sequences of the precore/core promoter gene, core promoter mutants in 12 patients were replaced by wild-type virus in three patients (25%), while precore mutants in four patients were replaced by the wild-type in three patients (75%). The results demonstrate the patterns of polymerase and precore/core promoter mutations in lamivudine-resistant hepatitis B viruses and the reversion from the mutant to the wild-type in some patients. In addition, despite several mutations in the polymerase during ADV therapy, ADV effectively suppressed HBV replication without the emergence of resistant viral mutants.     

Prevalence of precore-defective mutant of hepatitis B virus in HBV carriers

Two hundred and seventy-three serum specimens from hepatitis B virus (HBV) carriers were examined for the presence of a characteristic one point mutation at nucleotide (nt) 1896 from the EcoRI site of the HBV genome in the precore region (the preC mutant) using restriction fragment length polymorphism (RFLP) analysis. This assay approach could detect preC mutants or wild-type sequences when either form constituted more than 10% of the total sample. Overall, 65.5% (76/116) of HBeAg-positive carriers had only the preC wild-type. All HBeAg-positive asymptomatic carriers (n = 14) had only the preC wild-type. In patients with chronic hepatitis B and in anti-HBe-positive asymptomatic carriers, increased prevalence of the preC mutant was associated with the development of anti-HBe antibodies and normalization of the serum alanine aminotransferase concentration. Furthermore, 27 (29.0%) of 93 HBeAg-negative carriers had unexpectedly preC wild-type sequences only. Direct sequencing of the HBV precore region of HBV specimens from 24 patients revealed no mutation at nt 1896, supporting the specificity of the RFLP analysis. These results suggest that RFLP analysis was accurate for the detection of the preC mutation and that the absence of serum HBeAg cannot be explained solely by the dominance of the preC mutant. © 1995 Wiley-Liss, Inc.     

Sequential analyses of the mutations in the core upstream and precore regions of hepatitis B virus genome in anti-HBe positive-carriers developing acute exacerbation

The nucleotide sequences of the core upstream and precore regions (371 nucleotide length, nt. 1604-1974) of hepatitis B virus (HBV) were analysed sequentially in three subjects who were positive serorogically for anti-HBe and had acute clinical exacerbation after immunosuppressive treatment. These patients were asymptomatic HBV carriers before therapy. The results revealed that the mutant with an 8-bp deletion (nt. 1768–1775) located in the basic core promoter region was dominant in the asymptomatic HBV carrier phase in two of three subjects. After exacerbation, however, such mutant clones possessing 8-bp deletion disappeared or decreased in number and were replaced by the clones possessing a precore stop codon mutation G to A (nt. 1896) or by the clones possessing additional contiguous point mutations A to T (nt. 1762) and G to A (nt. 1764) and a new point mutation C to T (nt. 1653). Possible relationships between acute exacerbation of liver function accompanied by mutation and the transition of the dominant clones were discussed. J. Med. Virol. 53:266–272, 1997. © 1997 Wiley-Liss, Inc.     

GTPase activity is not essential for the interferon-inducible MxA protein to inhibit the replication of hepatitis B virus

Multiple studies have established that GTPase activity is critical for MxA to act against RNA viruses. Recently, it was shown that MxA can also restrict the replication of hepatitis B virus (HBV), a DNA virus, but the requirements for GTPase activity in inhibition of HBV by MxA remain unknown. Here, we report that GTPase-defective mutants (K83A, T103A, and L612K) can downregulate extracellullar HBsAg and HBeAg and reduce the expression of extra- and intracellular HBV DNA in HepG2 cells to levels similar to that achieved by wild-type MxA. Furthermore, TMxA and T103, two nuclear forms of wild-type MxA and a GTPase-defective mutant (T103A) could only slightly decrease the expression of extra- and intracellular HBV DNA in HepG2 cells. In conclusion, GTPase activity is not essential for MxA protein to inhibit HBV replication, and MxA may have only a minimal effect on the replicative cycle of HBV in the nucleus.     

Genetic heterogeneity in the precore region of hepatitis B virus in hepatitis B e antigen-negative chronic hepatitis B Patients: Spontaneous seroconversion and interferon-induced seroconversion

To elucidate the relationship between the clinical severity of chronic liver disease and the precore mutations in hepatitis B e antigen (HBeAg)-nega-tive hepatitis B virus (HBV) carriers, mutations were investigated in the precore region of HBV DNA in 20 chronic hepatitis B patients who sero-converted either spontaneously or after the administration of α-interferon (IFN), and 5 asymptomatic carriers. The precore mutation with a stop codon at nucleotide 1896 was found in all patients, irrespective of the histology and in all asymptomatic carriers. The second mutation at nucleotide 1899 was found in 40% of cases studied but always followed by the first mutation at nucleotide 1896. The mixed viral infection of precore mutant and wild-type HBV virus was found in 40% of seroconverted cases after IFN treatment and in sera of HBV carriers obtained within a year after the spontaneous Seroconversion. These data suggest that the precore mutants prevail over wild-type HBV in all HBeAg-negative HBV carriers within several years after the sero-conversion, but their prevalence could not confine the clinical severity of chronic liver disease. © 1995 Wiley-Liss, Inc.     

乙型肝炎病毒前C区和BCP区突变株复制质粒的构建

目的　构建乙型肝炎病毒 (HBV)前C区和基本核心启动子区 (BCP)突变株的复制质粒。方法　以含 1 2倍拷贝HBVDNA全基因的质粒 (pHBV1 2 )为工具 ,采用分子克隆、PCR定点诱变、限制性酶切长度多态性和序列分析等技术构建目的质粒。转染肝癌细胞株Huh7后 ,测定培养上清HBsAg、HBVDNA来了解病毒抗原的表达和病毒复制。结果　成功构建了 10种HBV全基因前C区 /BCP区突变的表达质粒 ,转染肝癌细胞株 ,获得病毒的表达和病毒颗粒的分泌。其中 ,pUC HBVT176 2、A176 4双突变以及pUC HBVT175 3突变株复制效率较高 ,转染细胞培养上清的HBVDNA为3 16× 10 5拷贝 ml。野生型复制子培养上清HBVDNA含量稍低于BCP突变复制子。结论　获得 10株含有不同前C区和BCP区突变的HBV全基因复制质粒 ,为体外进一步研究上述变异的生物学意义提供基本模型。     

A precore-defective mutant of hepatitis B virus associated with e antigen-negative chronic liver disease

The pathogenesis of chronic liver disease (CLD) due to persistent hepatitis B virus (HBV) infection has not been defined, but the disease activity is believed to correlate with the presence of hepatitis B e-antigen (HBeAg) antigenemia and high viremia. The molecular characterization of an HBV mutant isolated from an HBeAg-negative patient with severe CLD required amplification of the circulating HBV DNA (2 pg/ml) by the polymerase chain reaction (PCR). Direct sequencing of the nucleotides from five independent amplifications of the conserved precore region consistently revealed a G to A mutation in each of the two terminal codons of the precore region. Codon 28 was mutated from tryptophan-encoding TGG to a translational stop codon, TAG; codon 29 preceding the core initiation codon was changed from GGC to GAC. For biologic evaluation of these mutations on HBV replication and expression of HBeAg in vitro, HepG2 cells were transfected with cloned, recircularized mutant HBV DNA. The transfected cells contained subviral core particles in the cytoplasm and secreted mature HBV, without HBeAg, into the medium. The findings present the first evidence that complete HBV genomes can be amplified by PCR and are replication-competent in vitro. The data also indicate that HBeAg is not necessary for replication of HBV and furthermore suggest that HBeAg is not required for the progression of HBV-induced CLD.     

A hepatitis B virus mutant associated with an epidemic of fulminant hepatitis

BACKGROUND. A nosocomial outbreak of fulminant hepatitis B occurred in five patients in Haifa, Israel. Previous investigations identified the suspected source as a carrier of hepatitis B surface antigen who was positive for antibodies to hepatitis B e antigen and had chronic liver disease. We examined the strain of hepatitis B virus (HBV) that caused this epidemic, in order to identify specific mutations in the precore or core region. METHODS. The presence of HBV was identified by polymerase-chain-reaction amplification of viral DNA in serum from the source patient, the five patients with fulminant hepatitis B, and five controls with acute, self-limited hepatitis B. The amplified viral HBV DNA samples were then cloned and sequenced. RESULTS. Sequence analysis of viral DNA established that the same HBV mutant with two mutations in the precore region was present in the source patient and the five patients with fulminant hepatic failure. This HBV mutant had significant sequence divergence from other known HBV subtypes in the X, precore, and core regions. Cloned HBV DNA derived from a hospitalized patient who had subclinical hepatitis B at the same time as the outbreak and from four other control subjects with acute, self-limited hepatitis B all contained the wild-type sequence in the precore region. CONCLUSIONS. In the outbreak we studied, a mutant hepatitis B viral strain was transmitted from a common source to five patients who subsequently died of fulminant hepatitis B infection. Naturally occurring viral mutations hepatitis B infection. Naturally occurring viral mutations in the HBV genome may predispose the infected host to more severe liver injury.     

Prevalence of precore mutants in anti-HBe-positive hepatitis B virus carriers in Germany.

Hepatitis B virus (HBV) precore mutants are associated often with highly productive infection in hepatitis B surface antigen (HBsAg) carriers lacking hepatitis B e antigen (HBeAg) but positive for anti-HBe, rendering serological identification of infectious individuals unreliable. Although considered initially to be limited mostly to the Mediterranean area, more recent studies suggest a significant presence of these mutants in northern European countries. The sequence of the precore region was determined and examined for mutations from HBV isolates of 99 German chronic HBsAg carriers positive for HBV-DNA and either HBeAg (n = 15) or anti-HBe (n = 84). In addition, clinical data of individuals carrying wild-type virus and those with precore mutants were compared. HBV precore mutants were found in more than half (44/84) of all HBeAg-negative, anti-HBe-positive virus carriers. There was no difference between carriers of wild-type and precore mutant HBV in the level of viremia or in the clinical course of chronic infection. In conclusion, HBV precore mutants are common in Germany and can therefore present a diagnostic problem for serological testing. However, precore mutants do not appear to have a detrimental effect on the course of chronic HBV infection.