State Key Lab of Virology, Wuhan Institute of Virology, Chinese Academy of Sciences, Wuhan, China.
State Key Lab of Virology, Wuhan Institute of Virology, Chinese Academy of Sciences, Wuhan, China; University of Chinese Academy of Sciences, Beijing, China.
Virus Res. 2015 Dec 2;210:119-25. doi: 10.1016/j.virusres.2015.08.004. Epub 2015 Aug 7.
Immune escape mutants with mutations in the hepatitis B surface antigen (HBsAg) major hydrophilic region (MHR) often emerge in association with diagnostic failure or breakthrough of HBV infection in patients with anti-HBs antibodies. Some mutants harboring substitutions to Asn in HBsAg MHR may have an additional potential N-glycosylation site. We have previously showed that sT123N substitution could generate additional N-glycosylated forms of HBsAg. In the present study, 1.3-fold-overlength HBV genomes containing the sT123N substitution were digested from the pHBV1.3-sT123N construct and subcloned into the pAAV vector to generate pAAV1.3-sT123N for hydrodynamic injection (HI) in mice. Viral expression and replication were phenotypically characterized by transient transfection. The results demonstrated that sT123N substitution impaired virion secretion, resulting in intracellular retention of HBcAg. Using the HBV HI mouse model, we found that mice mounted significantly stronger antibody responses to HBsAg and HBcAg, which accelerated HBsAg clearance. Thus, additional N-glycosylation generated by amino acid substitutions in HBsAg MHR may significantly modulate specific host immune responses and influence HBV infection in vivo. Our results help further the understanding of the role of immune escape mutants with N-linked glycosylation in the biology of HBV infection.
免疫逃逸突变体在乙肝表面抗原(HBsAg)主要亲水区域(MHR)中发生突变,通常与抗 HBs 抗体患者的 HBV 感染诊断失败或突破有关。一些在 HBsAg MHR 中具有取代天冬酰胺的突变体可能具有额外的潜在 N-糖基化位点。我们之前已经表明,sT123N 取代可以产生 HBsAg 的额外 N-糖基化形式。在本研究中,从 pHBV1.3-sT123N 构建体中消化包含 sT123N 取代的 1.3 倍超长度 HBV 基因组,并将其亚克隆到 pAAV 载体中,以生成用于在小鼠中进行水力注射(HI)的 pAAV1.3-sT123N。病毒表达和复制通过瞬时转染进行表型特征分析。结果表明,sT123N 取代损害了病毒粒子的分泌,导致 HBcAg 在细胞内滞留。使用 HBV HI 小鼠模型,我们发现小鼠对 HBsAg 和 HBcAg 的抗体反应明显增强,从而加速了 HBsAg 的清除。因此,HBsAg MHR 中氨基酸取代产生的额外 N-糖基化可能显著调节宿主的特异性免疫反应,并影响体内 HBV 感染。我们的研究结果有助于进一步了解具有 N 连接糖基化的免疫逃逸突变体在 HBV 感染生物学中的作用。
