Kinetics of hepatitis B surface antigen decline during 3 years of telbivudine treatment in hepatitis B e antigen-positive patients.

UNLABELLED: The impact of prolonged direct antiviral therapy on hepatitis B surface antigen (HBsAg) levels in patients with chronic hepatitis B is poorly understood. We quantitatively assessed serum HBsAg levels during 3 years of telbivudine treatment, as well as their relationship with virologic and biochemical characteristics in 162 hepatitis B e antigen-positive patients who maintained undetectable serum hepatitis B virus (HBV) DNA long-term. Telbivudine treatment progressively reduced serum HBsAg levels (mean ± SD) from baseline (3.8 ± 0.6 log10 IU/mL) to treatment week 24 (3.4 ± 0.7 log10 IU/mL), treatment year 1 (3.3 ± 0.8 log10 IU/mL), and treatment year 3 (3.0 ± 1.4 log10 IU/mL) (P <0.0001). In this patient population, HBsAg loss was observed in nine (6%) of 162 patients through year 3. During the first year of treatment, three patterns of HBsAg decline were observed: rapid (≥ 1 log10 IU/mL) in 32 patients, slow (0-1 log10 IU/mL) in 74 patients, and steady levels in 56 patients. These findings were associated with different likelihoods of HBsAg loss during long-term telbivudine therapy. Eight of 32 patients with rapid HBsAg decline versus none of 56 patients with steady HBsAg levels achieved HBsAg loss at year 3 (P = 0.0024). HBV genotype was a significant determinant for HBsAg kinetics, with the fastest decline in genotype A patients. In patients with subsequent HBsAg loss, viral antigens were already undetectable in liver biopsy samples after 1 year of treatment. This was associated with markedly enhanced antiviral T cell reactivity. CONCLUSION: In patients who have effective suppression of viral replication during telbivudine treatment, a rapid decline in serum HBsAg levels during the first year may identify those with a greater likelihood of achieving HBsAg clearance.

IL-10 protects monocytes and macrophages from complement-mediated lysis.

Phagocytes, such as monocytes and macrophages, are important cells of the innate immunity in the defense against microbes. So far, it is unclear how these cells survive at the site of combat against microbes, where a hostile inflammatory environment prevails with strong complement activity. We hypothesized that IL-10, a key cytokine involved in the resolution of inflammation, induces resistance to complement attack. Here, we demonstrate for the first time such a cell-protective effect of IL-10 on human monocytes and macrophages. IL-10 is indeed able to protect these cell types in an in vitro model of complement lysis triggered by an anti-MHCI antibody or by binding of zymosan. Investigating potential underlying mechanisms, we found that IL-10 up-regulated the expression of complement regulatory membrane protein CD59 and the general cell-protective stress protein HO-1 in human monocytes. However, further functional analysis failed to link these individual IL-10-mediated effects with the increased protection from complement lysis. Blocking the protective effect of CD59 with an antibody increased complement lysis but did not abrogate the IL-10-protective effect. Interestingly, chemical interference with HO-1 activity did abrogate the protective effect of IL-10, but siRNA-mediated knockdown of HO-1 did not confirm this observation. Our results suggest that IL-10 generates pathogen-clearing phagocytes, which are resistant to complement lysis and thereby, enabled to survive longer in a hostile inflammatory environment.