Xuanyong Lu

Alkylated Porphyrins Have Broad Antiviral Activity against Hepadnaviruses, Flaviviruses, Filoviruses, and Arenaviruses

ABSTRACT We screened ∼2,200 compounds known to be safe in people for the ability to reduce the amount of virion-associated hepatitis B virus (HBV) DNA in the culture medium of producer cells. These efforts led to the discovery of an alkylated porphyrin, chlorophyllide, as the compound that achieved the greatest reduction in signal. Here we report that chlorophyllide directly and quantitatively disrupted HBV virions at micromolar concentrations, resulting in the loss of all detectable virion DNA, without detectably affecting cell viability or intracellular viral gene products. Chemophores of chlorophyllide were also tested. Chlorin e6, a metal-free chlorophyllide-like molecule, showed the strongest antiviral activity against HBV as well as profound antiviral effects on other enveloped viruses, such as hepatitis C virus (HCV), human immunodeficiency virus (HIV), dengue virus (DENV), Marburg virus (MARV), Tacaribe virus (TCRV), and Junin viruses (JUNV). Remarkably, chlorin e6 inactivated DENV at subnanomolar-level concentrations. However, the compound had no antiviral effect against encephalomyocarditis virus and adenovirus, suggesting that chlorin e6 may be less active or inactive against nonenveloped viruses. Although other porphyrin derivatives have been previously reported to possess antiviral activity, this is the first analysis of the biochemical impact of chlorophyllide and chlorin e6 against HBV and of the dramatic anti-infectivity impact upon DENV. The possible application of this family of compounds as antiviral agents, as microbicides and systemic virus neutralizing agents, is discussed.

Hepatitis B Virus-Mediated Changes of Apolipoprotein mRNA Abundance in Cultured Hepatoma Cells

ABSTRACT An inverse correlation between hepatitis B virus (HBV) and steady-state levels of apolipoprotein AI and CIII mRNAs was observed in two hepatoma cell lines. Analysis of a third line containing an inducible viral genome implicated viral pregenomic RNA in apolipoprotein mRNA reduction. We conclude that HBV alters infected cells despite the absence of overt cytopathogenicity.

Hepatitis B and Hepatitis C Virus Replication Upregulates Serine Protease Inhibitor Kazal, Resulting in Cellular Resistance to Serine Protease-Dependent Apoptosis

ABSTRACT Hepatitis B and C viruses (HBV and HCV, respectively) are different and distinct viruses, but there are striking similarities in their disease potential. Infection by either virus can cause chronic hepatitis, liver cirrhosis, and ultimately, liver cancer, despite the fact that no pathogenetic mechanisms are known which are shared by the two viruses. Our recent studies have suggested that replication of either of these viruses upregulates a cellular protein called serine protease inhibitor Kazal (SPIK). Furthermore, the data have shown that cells containing HBV and HCV are more resistant to serine protease-dependent apoptotic death. Since our previous studies have shown that SPIK is an inhibitor of serine protease-dependent apoptosis, it is hypothesized that the upregulation of SPIK caused by HBV and HCV replication leads to cell resistance to apoptosis. The evasion of apoptotic death by infected cells results in persistent viral replication and constant liver inflammation, which leads to gradual accumulation of genetic changes and eventual development of cancer. These findings suggest a possibility by which HBV and HCV, two very different viruses, can share a common mechanism in provoking liver disease and cancer.

The Alkylated Imino Sugar, n-(n-Nonyl)-Deoxygalactonojirimycin, Reduces the Amount of Hepatitis B Virus Nucleocapsid in Tissue Culture

ABSTRACT n-(n-Nonyl)-deoxygalactonojirimycin (n,n-DGJ), an alkylated imino sugar, reduces the amount of HBV DNA produced within the stably transfected HBV-producing HepG2.2.15 line in culture and is under consideration for development as a human therapeutic. n,n-DGJ does not appear to inhibit HBV DNA polymerase activity or envelop antigen production (A. Mehta, S. Carrouee, B. Conyers, R. Jordan, T. Butters, R. A. Dwek, and T. M. Block, Hepatology 33:1488-1495, 2001), and the mechanism of antiviral action is unknown. In this study, the step in the virus life cycle affected by n,n-DGJ was explored. Using Northern analysis and immunoprecipitation with anti-HBc antibody, we found that, under conditions in which cell viability was not affected but viral DNA production was substantially reduced, neither the amount of HBV transcription products nor the core polypeptide was detectably reduced. However, the pregenomic RNA, endogenous polymerase activity, and core polypeptide sedimenting in sucrose gradients with a density consistent with that of assembled nucleocapsids were significantly less in the HepG2.2.15 cells incubated with n,n-DGJ. These data suggest that n,n-DGJ either prevents the maturation of HBV nucleocapsids or destabilizes the formed nucleocapsids. Although the cellular and viral mediators of this inhibition are not known, depletion of nucleocapsid has been attributed to some other compounds as well as interferons mechanism of anti-HBV action. The similarities and differences between this alkylated imino sugar and these other mediators are discussed.

Hepatitis B virus MHBs antigen is selectively sensitive to glucosidase-mediated processing in the endoplasmic reticulum.

Previous studies have shown that hepatitis B virus (HBV) secretion from HepG 2.2.15 cells is prevented by inhibitors of the endoplasmic reticulum (ER) glucosidase under conditions where secretion of cellular glycoproteins are not detectably affected. The 2.2.15 cells are derived from HepG2 and contain intact dimers of the viral genome. They produce and secrete infectious HBV. The secretion of the viral envelope polypeptide, MHBs, was selectively and quantitatively reduced from 2.2.15 cells in which glucosidase was inhibited, whereas the envelope polypeptide, SHBs, was relatively insensitive, being as resistant as were most host glycoproteins. Because 2.2.15 cells express all HBV ORFs, it seemed possible that the sensitivity of MHBs secretion involved its interaction with the viral nucleocapsid or other viral gene products. The work reported here showed that MHBs secretion from HepG2 cells transfected with a plasmid that expresses only the MHBs polypeptide was as sensitive to glucosidase inhibitors as it was from 2.2.15 cells. These data show that the sensitivity of the MHBs polypeptide secretion to glucosidase inhibitors is entirely encrypted within its structural gene. The reasons the MHBs polypeptide, but not SHBs, is so sensitive to glucosidase processing are discussed.

Tumor-associated protein SPIK/TATI suppresses serine protease dependent cell apoptosis

Serine protease dependent cell apoptosis (SPDCA) is a recently described caspase independent innate apoptotic pathway. It differs from the traditional caspase dependent apoptotic pathway in that serine proteases, not caspases, are critical to the apoptotic process. The mechanism of SPDCA is still unclear and further investigation is needed to determine any role it may play in maintaining cellular homeostasis and development of disease. The current knowledge about this pathway is limited only to the inhibitory effects of some serine protease inhibitors. Synthetic agents such as pefabloc, AEBSF and TPCK can inhibit this apoptotic process in cultured cells. There is little known, however, about biologically active agents available in the cell which can inhibit SPDCA. Here, we show that over-expression of a cellular protein called serine protease inhibitor Kazal (SPIK/TATI/PSTI) results in a significant decrease in cell susceptibility to SPDCA, suggesting that SPIK is an apoptosis inhibitor suppressing this pathway of apoptosis. Previous work has associated SPIK and cancer development, indicating that this finding will help to open the doorway for further study on the mechanism of SPDCA and the role it may play in cancer development.

α-Glucosidase Inhibitors Have a Prolonged Antiviral Effect against Hepatitis B Virus through the Sustained Inhibition of the Large and Middle Envelope Glycoproteins

Previous work has shown that the secretion of enveloped hepatitis B virus (HBV) DNA and the HBV middle envelope protein (MHBs) are sensitive to glucosidase inhibition. Here, it is shown that HBV DNA secretion remains depressed after the removal of the glucosidase inhibitor and long after glucosidase function returns to normal. For example, glycoprocessing and the secretion of α-1 anti-trypsin returned to normal within 3 h of the removal of the glucosidase inhibitor. In contrast, the secretion of HBV did not return to normal for more than 7 days after the removal of the inhibitor. Consistent with the inhibition of HBV virion secretion, the levels of HBV L and HBV M proteins were also reduced by treatment with the glucosidase inhibitor and remained reduced for 7 days after compound withdrawal. The implications of the prolonged antiviral effect against HBV and the use of glucosidase inhibitors as antiviral agents are discussed.

Role of the inflammatory protein serine protease inhibitor Kazal in preventing cytolytic granule granzyme A-mediated apoptosis

Serine protease inhibitor Kazal (SPIK) is an inflammatory protein whose levels are elevated in numerous cancers. However, the role of this protein in cancer development is unknown. We have recently found that SPIK suppresses serine protease‐dependent cell apoptosis. Here, we report that anti‐SPIK antibodies can co‐immmunoprecipitate serine protease granzyme A (GzmA), a cytolytic granule secreted by cytotoxic T lymphocytes and natural killer cells during immune surveillance, and that SPIK suppresses GzmA‐induced cell apoptosis. Deletion studies show that the C3–C4 region of SPIK is critical for this suppression. These studies suggest that over‐expression of SPIK may prevent GzmA‐mediated immune‐killing, thereby establishing the tolerance of cancer cells to the body’s immune surveillance system. Suppression of over‐expressed SPIK can restore the susceptibility of these cells to apoptotic death triggered by GzmA. This finding implies that it is possible to overcome tolerance of cancer cells to the body’s immune surveillance system and restore the GzmA‐mediated immune‐killing by suppressing the over‐expression of SPIK.

Role of glycan processing in hepatitis B virus envelope protein trafficking.

We have previously shown that the glucosidase inhibitor, NBDNJ, prevents HBV virion but not subviral particle secretion from stably transfected HepG2 cells (Block et al, 1994). Moreover, the inhibition of virion secretion was due to the inhibition of the ER glucosidase (Lu et al, 1995). To determine which envelope protein functions require glycan processing and to understand the consequences to a glycoprotein of bearing unprocessed glycan, it was of interest to know the specific steps in the virus life cycle which were upset in cells in which ER glucosidase was inhibited