Wing-Pui Kong

P53 inhibition by the LANA protein of KSHV protects against cell death

Kaposis sarcoma-associated herpesvirus (KSHV), or human herpesvirus 8, has been implicated in the development of Kaposis sarcoma (KS) and several B-cell lymphoproliferative diseases. Most cells in lesions derived from these malignancies are latently infected, and different viral gene products have been identified in association with lytic or latent infection by KSHV. The latency-associated nuclear antigen (LANA), encoded by open reading frame 73 of the KSHV genome, is a highly immunogenic protein that is expressed predominantly during viral latency, in most KS spindle cells and in cell lines established from body-cavity-based lymphomas. Antibodies to LANA can be detected in a high percentage of HIV-infected individuals who subsequently develop KS, although its role in disease pathogenesis is not completely understood. p53 is a potent transcriptional regulator of cell growth whose induction leads either to cell-cycle arrest or apoptosis. Loss of p53 function correlates with cell transformation and oncogenesis, and several viral oncoproteins interact with p53 and modulate its biological activity. Here we show that LANA interacts with the tumour suppressor protein p53 and represses its transcriptional activity. This viral gene product further inhibits the ability of p53 to induce cell death. We propose that LANA contributes to viral persistence and oncogenesis in KS through its ability to promote cell survival by altering p53 function.

A DNA vaccine induces SARS coronavirus neutralization and protective immunity in mice

Public health measures have successfully identified and contained outbreaks of the severe acute respiratory syndrome (SARS) coronavirus (SARS-CoV), but concerns remain over the possibility of future recurrences. Finding a vaccine for this virus therefore remains a high priority. Here, we show that a DNA vaccine encoding the spike (S) glycoprotein of the SARS-CoV induces T cell and neutralizing antibody responses, as well as protective immunity, in a mouse model. Alternative forms of S were analysed by DNA immunization. These expression vectors induced robust immune responses mediated by CD4 and CD8 cells, as well as significant antibody titres, measured by enzyme-linked immunosorbent assay. Moreover, antibody responses in mice vaccinated with an expression vector encoding a form of S that includes its transmembrane domain elicited neutralizing antibodies. Viral replication was reduced by more than six orders of magnitude in the lungs of mice vaccinated with these S plasmid DNA expression vectors, and protection was mediated by a humoral but not a T-cell-dependent immune mechanism. Gene-based vaccination for the SARS-CoV elicits effective immune responses that generate protective immunity in an animal model.

pH-Dependent Entry of Severe Acute Respiratory Syndrome Coronavirus Is Mediated by the Spike Glycoprotein and Enhanced by Dendritic Cell Transfer through DC-SIGN

ABSTRACT The severe acute respiratory syndrome coronavirus (SARS-CoV) synthesizes several putative viral envelope proteins, including the spike (S), membrane (M), and small envelope (E) glycoproteins. Although these proteins likely are essential for viral replication, their specific roles in SARS-CoV entry have not been defined. In this report, we show that the SARS-CoV S glycoprotein mediates viral entry through pH-dependent endocytosis. Further, we define its cellular tropism and demonstrate that virus transmission occurs through cell-mediated transfer by dendritic cells. The S glycoprotein was used successfully to pseudotype replication-defective retroviral and lentiviral vectors that readily infected Vero cells as well as primary pulmonary and renal epithelial cells from human, nonhuman primate, and, to a lesser extent, feline species. The tropism of this reporter virus was similar to that of wild-type, replication-competent SARS-CoV, and binding of purified S to susceptible target cells was demonstrated by flow cytometry. Although myeloid dendritic cells were able to interact with S and to bind virus, these cells could not be infected by SARS-CoV. However, these cells were able to transfer the virus to susceptible target cells through a synapse-like structure. Both cell-mediated infection and direct infection were inhibited by anti-S antisera, indicating that strategies directed toward this gene product are likely to confer a therapeutic benefit for antiviral drugs or the development of a SARS vaccine.

Overcoming Immunity to a Viral Vaccine by DNA Priming before Vector Boosting

ABSTRACT Replication-defective adenovirus (ADV) and poxvirus vectors have shown potential as vaccines for pathogens such as Ebola or human immunodeficiency virus in nonhuman primates, but prior immunity to the viral vector in humans may limit their clinical efficacy. To overcome this limitation, the effect of prior viral exposure on immune responses to Ebola virus glycoprotein (GP), shown previously to protect against lethal hemorrhagic fever in animals, was studied. Prior exposure to ADV substantially reduced the cellular and humoral immune responses to GP expressed by ADV, while exposure to vaccinia inhibited vaccine-induced cellular but not humoral responses to GP expressed by vaccinia. This inhibition was largely overcome by priming with a DNA expression vector before boosting with the viral vector. Though heterologous viral vectors for priming and boosting can also overcome this effect, the paucity of such clinical viral vectors may limit their use. In summary, it is possible to counteract prior viral immunity by priming with a nonviral, DNA vaccine.

PROPAGATION OF A HUMAN HERPESVIRUS FROM AIDS-ASSOCIATED KAPOSI'S SARCOMA

BACKGROUND Although unique DNA sequences related to gammaherpesviruses have been found in Kaposis sarcoma lesions, it is uncertain whether this DNA encodes a virus that is able to reproduce. METHODS We isolated and propagated a filterable agent whose DNA sequences were found to be identical to those of the Kaposis sarcoma-associated herpesvirus (KSHV). We obtained early-passage spindle cells from skin lesions of patients with the acquired immunodeficiency syndrome (AIDS) who had Kaposis sarcoma and cultured them with cells of the human embryonal-kidney epithelial-cell line 293. We characterized the virus according to its effects on cellular morphology and viral replication and its appearance on electron microscopy. RESULTS KSHV was cytotoxic to 293 cells and was detected by the polymerase chain reaction (PCR) in infected cells but not uninfected ones. Cytotoxicity and positive PCR signals were consistently maintained with viral titers of 1 million per milliliter, for about 20 serial infections of 293 cells. The viral copy number was relatively low (1 to 10 copies per cell). Viral replication was confirmed by Southern blot analysis of DNA isolated from the enriched nuclear fraction of infected cells and by a semiquantitative PCR using dilutions of the lysates of infected cells to detect the 233-bp viral DNA fragment originally described in association with Kaposis lesions. Electron microscopy revealed herpesvirus-like particles in about 1 percent of cells from infected cultures, as compared with none in cells from uninfected cultures. CONCLUSIONS A herpesvirus with DNA sequences identical to those of KSHV can be propagated from skin lesions of patients with AIDS-associated Kaposis sarcoma.

Cross-Neutralization of 1918 and 2009 Influenza Viruses: Role of Glycans in Viral Evolution and Vaccine Design

The 1918 and 2009 pandemic influenza viruses are both inhibited by antibodies directed to an exposed region of the viral spike, but this region becomes shielded by glycans in influenza seasonal strains. Remembrance of Flus Past For those who hate needles, this past winter was not a good one. Not only did we have to get the usual seasonal flu shot, doctors recommended that we also get a second shot against another type of flu, a pandemic virus called 2009 H1N1. As the U.S. Centers for Disease Control warned, “A seasonal vaccine will not protect you against 2009 H1N1.” Also odd was the fact that the 2009 H1N1 pandemic flu seemed to spare older people; those age 65 and older were not considered at high risk as they are for seasonal flu. Wei et al. have now worked out why the 2009 H1N1 pandemic flu has these properties, showing how the virus is different from seasonal flu virus but similar to the pandemic flu that swept the globe in 1918. The authors injected mice with seasonal flu viruses as well as with pandemic viruses from 1918 and 2009. The resulting antibodies raised in the mice could inhibit both pandemic viruses in culture and protected mice from infection with either 2009 or 1918 pandemic flu. Antibodies raised to the seasonal flu virus did not have this protective effect, although they protected against seasonal flu perfectly well. In investigating why, Wei et al. found that the key inhibitory antibodies raised to the pandemic flu strains bound to the exposed top of the spike protein, a molecule that projects from the virus and helps it to infect host cells. This immunogenic part of the spike is very similar in the 1918 and 2009 pandemic viruses. Even more interesting is how the seasonal flu escapes from these antibodies. Its spike protein has two sites, not present in the pandemic flu spike protein, to which sugar groups are added, shielding the seasonal flu spike protein from inhibition by the antibodies that act against the pandemic strains. Pandemic flu viruses evolve into seasonal flu varieties, and the authors suggest that one of the key evolutionary steps is the acquisition of the sites for sugar groups on the spike protein. These changes allow the virus to infect people with preexisting immunity to pandemic flu. The results of Wei et al. may also explain the relative resistance of older people to the present flu pandemic: Persistent immunity to the 1918 flu or its close relatives from childhood may inhibit the unprotected spike protein of the current 2009 pandemic flu virus and, thus, its ability to infect host cells. New strains of H1N1 influenza virus have emerged episodically over the last century to cause human pandemics, notably in 1918 and recently in 2009. Pandemic viruses typically evolve into seasonal forms that develop resistance to antibody neutralization, and cross-protection between strains separated by more than 3 years is uncommon. Here, we define the structural basis for cross-neutralization between two temporally distant pandemic influenza viruses—from 1918 and 2009. Vaccination of mice with the 1918 strain protected against subsequent lethal infection by 2009 virus. Both were resistant to antibodies directed against a seasonal influenza, A/New Caledonia/20/1999 (1999 NC), which was insensitive to antisera to the pandemic strains. Pandemic strain–neutralizing antibodies were directed against a subregion of the hemagglutinin (HA) receptor binding domain that is highly conserved between the 1918 and the 2009 viruses. In seasonal strains, this region undergoes amino acid diversification but is shielded from antibody neutralization by two highly conserved glycosylation sites absent in the pandemic strains. Pandemic HA trimers modified by glycosylation at these positions were resistant to neutralizing antibodies to wild-type HA. Yet, antisera generated against the glycosylated HA mutant neutralized it, suggesting that the focus of the immune response can be selectively changed with this modification. Collectively, these findings define critical determinants of H1N1 viral evolution and have implications for vaccine design. Immunization directed to conserved receptor binding domain subregions of pandemic viruses could potentially protect against similar future pandemic viruses, and vaccination with glycosylated 2009 pandemic virus may limit its further spread and transformation into a seasonal influenza.

Rapid development of a DNA vaccine for Zika virus

A DNA vaccine candidate for Zika The ongoing Zika epidemic in the Americas and the Caribbean urgently needs a protective vaccine. Two DNA vaccines composed of the genes that encode the structural premembrane and envelope proteins of Zika virus have been tested in monkeys. Dowd et al. show that two doses of vaccine given intramuscularly completely protected 17 of 18 animals against Zika virus challenge. A single low dose of vaccine was not protective but did reduce viral loads. Protection correlated with serum antibody neutralizing activity. Phase I clinical trials testing these vaccines are already ongoing. Science, this issue p. 237 DNA-vaccine–induced neutralizing antibodies largely protect monkeys after experimental challenge by virus infection. Zika virus (ZIKV) was identified as a cause of congenital disease during the explosive outbreak in the Americas and Caribbean that began in 2015. Because of the ongoing fetal risk from endemic disease and travel-related exposures, a vaccine to prevent viremia in women of childbearing age and their partners is imperative. We found that vaccination with DNA expressing the premembrane and envelope proteins of ZIKV was immunogenic in mice and nonhuman primates, and protection against viremia after ZIKV challenge correlated with serum neutralizing activity. These data not only indicate that DNA vaccination could be a successful approach to protect against ZIKV infection, but also suggest a protective threshold of vaccine-induced neutralizing activity that prevents viremia after acute infection.

Enhanced Mucosal Immunoglobulin A Response of Intranasal Adenoviral Vector Human Immunodeficiency Virus Vaccine and Localization in the Central Nervous System

ABSTRACT Replication-defective adenovirus (ADV) vectors represent a promising potential platform for the development of a vaccine for AIDS. Although this vector is typically administered intramuscularly, it would be desirable to induce mucosal immunity by delivery through alternative routes. In this study, the immune response and biodistribution of ADV vectors delivered by different routes were evaluated. ADV vectors expressing human immunodeficiency virus type 1 (HIV-1) Gag, Pol, and Env were delivered intramuscularly or intranasally into mice. Intranasal immunization induced greater HIV-specific immunoglobulin A (IgA) responses in mucosal secretions and sera than in animals with intramuscular injection, which showed stronger systemic cellular and IgG responses. Administration of the vaccine through an intranasal route failed to overcome prior ADV immunity. Animals exposed to ADV prior to vaccination displayed substantially reduced cellular and humoral immune responses to HIV antigens in both groups, though the reduction was greater in animals immunized intranasally. This inhibition was partially overcome by priming with a DNA expression vector expressing HIV-1 Gag, Pol, and Env before boosting with the viral vector. Biodistribution of recombinant adenovirus (rADV) vectors administered intranasally revealed infection of the central nervous system, specifically in the olfactory bulb, possibly via retrograde transport by olfactory neurons in the nasal epithelium, which may limit the utility of this route of delivery of ADV vector-based vaccines.

Heterologous Envelope Immunogens Contribute to AIDS Vaccine Protection in Rhesus Monkeys

ABSTRACT Because a strategy to elicit broadly neutralizing anti-human immunodeficiency virus type 1 (HIV-1) antibodies has not yet been found, the role of an Env immunogen in HIV-1 vaccine candidates remains undefined. We sought to determine whether an HIV-1 Env immunogen genetically disparate from the Env of the challenge virus can contribute to protective immunity. We vaccinated Indian-origin rhesus monkeys with Gag-Pol-Nef immunogens, alone or in combination with Env immunogens that were either matched or mismatched with the challenge virus. These animals were then challenged with a pathogenic simian-human immunodeficiency virus. The vaccine regimen included a plasmid DNA prime and replication-defective adenoviral vector boost. Vaccine regimens that included the matched or mismatched Env immunogens conferred better protection against CD4+ T-lymphocyte loss than that seen with comparable regimens that did not include Env immunogens. This increment in protective immunity was associated with anamnestic Env-specific cellular immunity that developed in the early days following viral challenge. These data suggest that T-lymphocyte immunity to Env can broaden the protective cellular immune response to HIV despite significant sequence diversity of the strains of the Env immunogens and can contribute to immune protection in this AIDS vaccine model.

Human Immunodeficiency Virus Type 1-Specific Immunity after Genetic Immunization Is Enhanced by Modification of Gag and Pol Expression

ABSTRACT Immunity to human immunodeficiency virus virion-like structures or a polyprotein has been examined after DNA immunization with Rev-independent expression vectors. A Gag-Pol fusion protein stimulated cytotoxic T lymphocyte and antibody responses to Gag and Pol, while a Gag-Pol pseudoparticle did not elicit substantial Pol responses. This fusion protein may be useful for AIDS vaccines.