HBe antigen loss during lamivudine therapy is not caused by mutations in precore and core promoter genes in patients with chronic hepatitis B

HBe antigen (HBeAg) loss or seroconversion can occur during lamivudine therapy. The purpose of this study was to analyze nucleotide sequences in precore and core promoter regions, and examine the influence of mutations in these regions on the disappearance of HBeAg during lamivudine therapy. Serial serum samples were obtained from 51 patients (HBeAg loss in 26 patients) at commencement of therapy (baseline) and after 1 year of lamivudine therapy. Serum samples were amplified with PCR and nucleotide sequences of HBV were analyzed. At baseline, a precore stop codon mutation (A1896) was identified in 8 of 26 HBeAg loss patients and in 8 of 25 HBeAg non-loss patients. At 1 year, precore mutation was observed in 4 of 14 patients analyzed who showed HBeAg loss. At 1 year, however, a precore mutation was observed also in 3 of 9 analyzed patients who showed no HBeAg loss. Core promoter mutations were noted in 21 of 26 HBeAg loss patients and in 20 of 25 HBeAg non-loss patients. At 1 year, core promoter mutations were noted in 11 of 14 HBeAg loss patients and in 8 of 9 HBeAg non-loss patients. Our data suggested that during lamivudine therapy, core promoter and precore mutations do not influence HBeAg loss or seroconversion but may reduce the viral level upon HBeAg loss or seroconversion.     

Hepatitis B e antigen‐negative mutations in the precore and core promoter regions in Korean patients

Most patients with hepatitis B e antigen (HBeAg)‐negative chronic hepatitis B have variants of the hepatitis B virus (HBV) that include mutations in the precore or core promoter regions of the HBV genome. The aim of this study was to investigate the patterns of precore and core promoter mutations and their relationship to HBeAg expression in Korean patients. Four hundred seventy‐five Korean patients with chronic HBV infection between February 1995 and December 2003 were enrolled in this study. There were 236 HBeAg‐positive and 239 HBeAg‐negative patients. Blood samples were tested for HBsAg, anti‐HBs, HBeAg, hepatitis B e antibody (anti‐HBe), liver function tests, and serum HBV DNA. Mutations in the precore and core promoter regions were determined by direct sequencing. In the core promoter region, the C1740, C1753, T1762/A1764, and T1766 mutations were associated with HBeAg escape (all; P < 0.05). In the precore region, a higher frequency of the C1802, A1828, T1846, A1850, C1858, T1862, and A1896 mutations was found in HBeAg‐negative patients (all; P < 0.05). In particular, the A1896 mutation was associated with high serum levels of ALT and HBV DNA in HBeAg‐negative patients (P = 0.014 and 0.026, respectively). Mutations around the Kozak sequence (nucleotides 1809–1812) were found in 6.7% of patients and were not associated with undetectable HBeAg (P = 0.13). In Korean patients, various mutations in the precore and core promoter regions were associated with HBeAg escape and amelioration of hepatic inflammation in HBeAg‐ negative patients. Only the A1896 mutation contributed to HBeAg‐negative chronic hepatitis B. J. Med. Virol. 81:594–601, 2009 © 2009 Wiley‐Liss, Inc.     

Sequence analysis of hepatitis B virus genomes from an infant with acute severe hepatitis and a hepatitis B e antigen-positive carrier mother

It is well known that fulminant hepatitis B can occur in infants born to hepatitis B e antigen (HBeAg)-negative hepatitis B virus (HBV) carrier mothers, whereas fulminant hepatitis and severe hepatitis are uncommon in infants born to HBeAg-positive mothers. We have encountered an infant with severe acute hepatitis B born to a HBeAg-positive mother. The aim of this study was to determine whether HBV variants contribute to the pathogenesis of fulminant hepatitis and severe hepatitis in an infant born to an HBeAg-positive mother. The nucleotide sequence of HBV genomes from the infant and his HBeAg-positive carrier mother was analyzed. All HBV isolated from the infant and his mother were subtype adr. The sequences of the cloned HBV genomes, each including a part of the X and precore/core regions, isolated from the infant were almost identical (homology of 99.1-99.9%) to those from his mother. There was no mutation in any of the 17 clones examined at nucleotides 1762 and 1764 in the core promoter, which is reported to be associated with fulminant hepatitis. A point mutation at nucleotide 1758 in the second AT-rich region of the basic core promoter was present in all clones. None of the clones had a point mutation at nucleotide 1896 of the precore region. In this study, no specific HBV variants contributing to the development of neonatal severe hepatitis were found. There is a possibility that host factors rather than viral factors play an important role in some cases of severe neonatal hepatitis B.     

Precore/core promoter mutations and genotypes of hepatitis B virus in chronic hepatitis B patients with fulminant or subfulminant hepatitis

The association of precore stop codon mutation (A1896), dinucleotide mutation (T1762/A1764) in the basic core promoter of hepatitis B virus (HBV) genome, and genotype of HBV with fulminant or subfulminant hepatitis remains controversial. We studied HBV genotypes as well as mutations in the precore and basic core promoter regions in 18 hepatitis B carriers with fulminant or subfulminant hepatitis. Genotyping of HBV was performed by polymerase chain reaction-restriction fragment length polymorphism. The presence of A1896 in the precore gene and T1762/A1764 in the basic core promoter gene was determined by the polymerase chain reaction and by direct sequencing. Eighteen age- and sex-matched patients with chronic active hepatitis B served as controls. The HBV was of genotype B in 14, genotype C in 3, and unclassified in 1. Precore A1896 mutation occurred in 12 (67%) of the 18 patients. In contrast, the prevalence of basic core promoter mutation was only 17%. Nevertheless, the distribution of HBV genotype and the prevalence of precore A1896 mutation in the fulminant and subfulminant hepatitis patients were similar to those in 18 control patients. In conclusion, the genomic variability of HBV does not seem to contribute to the fulminant and subfulminant exacerbation of chronic hepatitis B in Taiwanese HBV carriers.     

Evolution of precore/core promoter mutations in hepatitis B carriers with hepatitis B e antigen seroreversion

The evolution of precore stop codon mutation (A1896) and dinucleotide mutation (T1762/A1764) in the basic core promoter (BCP) of hepatitis B virus (HBV) genome during transient seroconversion and seroreversion of hepatitis B e antigen (HBeAg) remains unclarified. Five HBeAg-positive HBV carriers who experienced transient seroconversion followed by seroreversion of HBeAg (Group I, 3.3%) and 3 HBeAg-negative HBV carriers with documented reversion of HBeAg (Group II, 2.5%) in a prospective cohort of 272 patients with chronic hepatitis B were thus identified. The sequential changes at the precore nucleotide 1896 and BCP dinucleotide 1762/1764 were determined by polymerase chain reaction and direct sequencing. At enrollement, precore A1896 and BCP T1762/A1764 were noted in 4 (50%) and 1 (13%) of the eight patients. During a median follow-up period of 58 months (range: 31-76 months), 12 episodes of transient HBeAg seroconversion followed by seroreversion were encountered in Group I patients and 3 episodes of HBeAg seroreversion in Group II patients. Accompanying acute exacerbations were found in two-thirds of patients with either HBeAg seroconversion or seroreversion. Overall, precore nucleotide A1896 remained identical in 73% and 83% of the seroconversion and seroreversion events, respectively. BCP dinucleotide T1762/A1764 remained unchanged in 94% and 92% of the seroconversion and seroreversion events, respectively. At the end of follow-up, only one had both precore and BCP mutations. In conclusion, these data suggested that HBeAg seroreversion might be due to the lack of sustained precore and BCP mutations after HBeAg seroconversion. Although uncommon, HBeAg seroreversion can be associated with hepatitis exacerbation.     

Prevalence of HBV core promoter/precore/core mutations in Gambian chronic carriers.

One hundred forty-two precore/core sequences were obtained from Gambian chronic hepatitis B virus (HBV) carriers and the predominant variants defined. The two point mutations, from A to T and G to A at nt positions 1762 and 1764 in the basic core promoter region, were found in only 7/99 (7%) of the samples where this region was sequenced. These mutations were found in both HBeAg-positive and -negative patients. The precore stop-codon mutation at nt position 1896 was found in 14/51 (27%) of HBeAg-negative samples, which is a lower prevalence rate in comparison with other parts of the world with high carrier rates. In HBeAg-positive patients the core amino acid sequences were conserved, but after seroconversion to anti-HBe significantly more changes were apparent. Several of the amino acid substitutions found have been described previously been in wild-type viruses of other genotypes.     

Clinical significance of hepatitis B virus (HBV) genotypes and precore and core promoter mutations affecting HBV e antigen expression in Taiwan

To assess the prevalence and clinical significance of hepatitis B virus (HBV) genotypes and precore and core promoter mutations in Taiwan, a cohort of 200 Taiwanese chronic hepatitis B patients was analyzed. The HBV genotypes and sequences of the precore and the core promoter regions were determined in 66 asymptomatic carriers and 134 patients who had liver biopsy-verified chronic hepatitis and liver cirrhosis. The HBV e-antigen (HBeAg)-negative patients had a higher frequency of mutations at core promoter nucleotides 1753 and 1773 and precore nucleotides 1846, 1896, and 1899 than HBeAg-positive patients. Among the 200 patients, the frequencies of genotype C, T1762 and A1764, C1753, T1766 and A1768, and A1896 mutations increased and the frequencies of T or G1752, T1773, G1799, and C1858 mutations decreased with advancing liver diseases. These factors were different between those with HBeAg-positive status and those with HBeAg-negative status. Based on multiple logistic regression analysis, the risk factors of liver cirrhosis for 200 patients were the presence of T1762 and A1764 mutations (odds ratio [OR] = 11.11; 95% confidence interval [CI] = 3.91 to 31.25; P < 0.001), age > or =35 years (OR = 3.42; 95% CI = 1.33 to 8.77; P = 0.011), and genotype C (OR = 2.87; 95% CI = 1.21 to 6.81; P = 0.017). Further categorical analysis found that 62.1% of patients with genotype C, T1762 and A1764 mutations and age > or =35 years had liver cirrhosis. None of the 55 patients infected with the genotype B, A1762 and G1764 wild type and age <35 years showed liver cirrhosis. In conclusion, our data suggest that pathogenic differences between HBeAg-positive and -negative patients may exist. In Taiwan, HBV genotype C and the T1762 and A1764 mutations may play a role in HBV-related liver cirrhosis, and these could serve as molecular markers for prediction of the clinical outcomes of chronic HBV patients.     

Base-pair Alterations in the Epsilon-lower Stem due to a Novel Double Substitution in the Precore Gene of HBV-e Negative Variant were Recovered by Secondary Mutations

The HBe negative phenotype, a natural precore mutant (G1896A/G1897A) of HBV with aborted HBeAg expression is known to cause chronic hepatitis. The destabilized C : G base-pairing in the lower stem of epsilon-hairpin due to G1896A substitution is reportedly compensated by a second C1858T mutation and suggested to play an important role in enhanced selection of the HBe negative variant. We undertook to investigate presence of such compensatory mutations at other positions by analyzing epsilon-sequences (nts. 1847-1907) as well as to look for their effect(s), if any, on the consensus sequence of the overlapping core-initiator of HBe negative HBV variants in CLD patients. Three of the 5 HBe negative patients had classical G1896A mutation having a second compensatory mutation at nt. 1858. One patient showed an additional G1897A substitution, presenting as a novel precore stop codon mutation (UGG-->UAA), followed by a compensatory mutation at position 1857. In the third patient, a G1899A substitution was seen which compensated the impaired U at position 1855. Other substitution and deletion mutations were also observed in the remaining epsilon-hairpin, which however, did not produce any compensatory mutation. Further, all the precore variants showed a conserved G at position 1904, important for the optimal context of their core-initiator which however, remained impaired with A (nt. 1850). Our results suggest that the nts. 1851-1859 and nts. 1895-1904 in the lower stem, and restoration of authentic base-pairings therein, maintain the structural integrity and stability of the epsilon-hairpin. This may have a role in the enhanced selection of the HBe negative variants and persistence of HBV infection in chronic liver disease patients.     

Epidemiology of precore mutants of hepatitis B in the United Kingdom

A point mutation assay was used to study the codon 28 and codon 1 precore mutant status of 310 chronic hepatitis B carriers (82 HBeAg positive and 228 HBeAg negative). Fourteen of 228 (6%) of HBeAg negative carriers had high levels of serum HBV DNA. Nine of these were explained by precore variants, three by core promoter variants, and two were not explained by recognised precore changes. Nested PCR detected serum HBV DNA in 36% (82/228) of HBeAg negative carriers and 63% (52/82) of these had precore variants. Four of 82 (4%) of the HBeAg positive carriers had precore variants, all as mixed mutant/wild type populations and evidence indicated that these carriers were seroconverting. Overall 23% (52/228) of HBeAg negative carriers had both serum HBV DNA and codon 1 or 28 precore mutations. A sexual transmission event from an HBeAg negative carrier with a relatively low serum HBV DNA level (10(4)-10(6) genome copies/ml) and only core promoter mutations was observed. Despite high rates of variant carriage in the antenatal sub-group perinatal transmission was not observed. The results of direct sequencing on 45 carriers validated the point mutation assay and also showed that codon 28 mutations were only seen in carriers with the genotype CCT at codon 15. For the Caucasian population a higher prevalence of codon 28 mutations (13/25 or 52%) than expected was seen. Liver biopsy data indicated that there was no link between the presence or absence of precore mutants and the severity of liver disease.     

Evolutionary perspective on hepatitis B virus with an expanded sampling strategy

To investigate the role hepatitis B e antigen (HBeAg) plays in the evolution of hepatitis B virus (HBV), we sequenced the basic core promoter (BCP) and precore (preC) regions of 348 clones total from ten HBV Chinese patients. Eleven mutations were more frequent in HBeAg-negative patients than in HBeAg-positive patients. Further, the sequencing of dozens of variants was found to be necessary to obtain mutation profiles. Phylogenetic and median-joining network analyses suggested that variants from each patient had a single common ancestor (monophyly). Higher haplotype and nucleotide diversities were identified in HBeAg-negative patients. Analysis of dN/dS suggested that viruses experiencing a stronger immune response had lower haplotype diversity. Because HBeAg seroconversion was associated with viral diversity it served as an indicator of HBV evolution. Significantly, this study indicated a larger sampling of variants from each patient was required to understand effectively the properties of HBV.     

Strong association between genotype F and hepatitis B virus (HBV) e antigen-negative variants among HBV-infected argentinean blood donors

A number of reports have indicated an increased risk of cirrhosis and hepatocellular carcinoma in hepatitis B virus (HBV)-infected individuals carrying HBV e antigen (HBeAg)-negative variants. Although distinct core promoter and precore mutations distributed according to geographical locality and viral genotype have been reported, epidemiological data from South America are still scarce. The prevalences of HBV genotypes and core promoter and precore polymorphisms in 75 HBeAg-negative Argentinean blood donors were surveyed. The observed frequencies of HBV genotypes were 64.0% for genotype F, 17.3% each for genotypes A and D, and 1.3% for genotype C. Genotype F strains were widely distributed and significantly more prevalent in the northern region of the country (P < 0.001). An overall high proportion of a stop codon mutation (UAG) at precore codon 28 (66.7%) was observed. Wild-type codon 28 (UGG) was present in 29.3% of the samples, and the remaining 4.0% of samples had mixed variants. The combination of A at nucleotide (nt) 1762 and G at nt 1764 of the core promoter was found in 58.7% of the samples. The variant profiles--T at nt 1762 and A at nt 1764 or A at nt 1762 and A at nt 1764--were detected in 28.0 and 1.3% of the samples, respectively. The observed core promoter polymorphisms could not be related to the ratio of HBeAg to anti-HBeAg antibody, HBV genotype, or precore codon 28 status. Nevertheless, a clear association of genotype F and a precore stop codon mutation was found (P < 0.05). In conclusion, HBV genotype F and mutant codon 28 strains predominated and were strongly associated in a geographically broad Argentinean blood donor population.     

Molecular epidemiology of hepatitis B virus in the United Republic of Tanzania

In the United Republic of Tanzania, 457 voluntary blood donors were enrolled in hepatitis B virus (HBV) serological screening; 4.8% (22/457) carried HBsAg, 13.6% (3/22) of whom were HBeAg-positive. The mean age among HBeAg-negative carriers was 31 years. HBV DNA was detectable in 81.8% (18/22), the mean level was 3.67 (+/-1.77) log copies/ml. Genotype A was determined in 90.9% (20/22) and 18/20 were classified into subgenotype Aa (Asia/Africa). The basal core promoter, precore and partial core nucleotide sequences were analyzed in the 18 strains; T1809/T1812 ("Kozak" sequence) and A/T1888 (encapsidation signal) variants were identified in 100% and 78%, respectively. The complete genome sequencing for one of the Tanzanian strains revealed no recombination. In conclusion, HBV seroprevalence is high among general population in Tanzania, and the HBV/Aa-infection is predominant. The indicated tendency to early HBeAg seroconversion and declining of the viral load should be confirmed further in case-control studies.     

Mutations in the Basal Core Promoter and Precore/Core Gene of Hepatitis B Virus in Patients with Chronic Active but not Acute Hepatitis B

 Around 5–10% of adults infected with hepatitis B virus (HBV) develop a chronic liver disease such as chronic active hepatitis (CAH), and it is unclear whether the clinical outcome depends solely on the immune response or whether viral factors also play a role. In this study, a search was therefore made for nucleotide mutations in the basic core promoter (BCP) and amino-acid substitutions in the precore/core region of HBV infecting patients with CAH or with acute hepatitis. The nucleotide sequences of the BCP and of the precore/core region were determined in virus from ten patients with CAH and ten with acute hepatitis. The precore/core sequences were also analysed in 14 additional patients (6 with CAH, 8 with acute hepatitis). In seven of the ten patients with CAH, five types of mutations were found in the BCP. Deletions in the precore/core region were observed in six patients. In all six patients where only the precore/core region was studied, amino-acid substitutions were present. In contrast, in the ten patients with acute hepatitis studied for BCP, a mutation was found in the BCP of one patient only. Of the 18 patients in whom the precore/core was studied, three had an amino-acid substitution in this region. The results show a clear link between CAH and both HBV BCP and precore/core region mutations, suggesting these mutations may play a role in the persistence of HBV infection.     

Evolution of wild-type and precore mutant HBV infection after liver transplantation

Recurrence of hepatitis B virus (HBV) infection after liver transplantation is associated with varying degree of graft damage. The aim of the study was to investigate longitudinally the changes of wild-type and precore A₁₈₉₆HBV mutant viral populations after reinfection and their impact on liver graft damage. The wild-type HBV and A₁₈₉₆HBV strains were quantitated before and serially after orthotopic liver transplantation (OLT) in 14 hepatitis B surface antigen (HBsAg)-positive liver graft recipients (4 hepatitis B e antigen [HBeAg]+; 10 anti-HBe+). Before OLT, the wild-type precore HBV was present in all 4 HBeAg-positive patients and in 2/10 anti-HBe-positive patients; a mixed virus population was present in 6 patients; and A₁₈₉₆HBV mutant alone in 2 patients. After OLT, A₁₈₉₆HBV mutant appeared and gradually accumulated in 5/6 patients who had the wild-type HBV before OLT and 1 of these patients seroconverted from HBeAg to anti-HBe 52 months after transplantation. A mixed HBV population was present continuously in 6 patients before and after OLT. Of the 2 patients with A₁₈₉₆HBV only pre-OLT, the wild type appeared in one patient and the other patient retained persistently the A₁₈₉₆HBV mutant. There was no relationship between liver graft histology and the type of viral population at reinfection or at the end of follow up. Changes in the HBV population occur during follow up of recurrent hepatitis B in liver transplant recipients with frequent accumulation of precore A₁₈₉₆HBV mutants, but the type of viral population does not determine the severity of hepatitis B in the graft. J. Med. Virol. 59:5–13, 1999. © 1999 Wiley-Liss, Inc.     

Presence of hepatitis B virus core promoter mutations pre-seroconversion predict persistent viral replication after HBeAg loss.

BACKGROUND: In patients with chronic hepatitis B virus (HBV) infection DNA levels do not always fall after anti-hepatitis B e (anti-HBe) seroconversion. OBJECTIVES: To follow longitudinally through HB e antigen (HBeAg) loss HBV DNA levels and core promoter/precore sequences in a cohort of 21 chronic HBV carriers. STUDY DESIGN: Treatment-na?ve HBeAg seropositive HBV carriers were monitored through HBeAg loss for between 2 and 22 years (mean 9.3). Core promoter/precore sequences, genotypes, HBV DNA levels and HBe status were determined. RESULTS: Patients were grouped into those in whom serum/plasma HBV DNA remained high after HBeAg loss (group 1, n=11; HBV DNA>5log(10)IU/ml) and those in whom HBV DNA declined (group 2, n=10). Re-appearance of HBeAg was seen in seven group 1 patients. Pre-seroconversion mutations in the core promoter region including A1762T and/or G1764A were detected more frequently in group 1 (P=0.031). Overall sequence changes at sites other than 1762/1764 were more common post-seroconversion in group 1 than group 2 patients (P=0.037). CONCLUSIONS: The presence of core promoter mutations prior to HBeAg loss identified those patients in whom HBV DNA persisted at high levels and was associated with temporary re-emergence of serum HBeAg. These patients may benefit from early anti-viral treatment.     

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.     

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.     

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.