We have previously shown that an Escherichia coli-expressed, denatured spike (S) protein fragment of the severe acute respiratory coronavirus, containing residues 1029 to 1192 which include the heptad repeat 2 (HR2) domain, was able to induce neutralizing polyclonal antibodies (C. The virus-cell membrane fusion event is an essential step in the entry process of all enveloped animal viruses, including important human pathogens such as influenza virus, human immunodeficiency virus (HIV) (8, 23), and the newly emerged severe acute respiratory syndrome coronavirus (SARS-CoV) (9). Following the binding to their receptors on the cell surface, virus-encoded membrane fusion proteins mediate the fusion process. In many but not all cases, the viral fusion proteins are proteolytically processed by host proteases into 2 subunits that remain closely associated with each other: a surface subunit with a receptor-binding site and a transmembrane subunit with a fusion peptide consisting of two or more heptad repeat domains. Upon interaction of the fusion protein with a cellular receptor, the buried fusion peptide is exposed and inserted into the membrane of the target cell. A series of conformational changes trigger virus-cell fusion activity (9) and lead to the unloading of the viral genome into cells. Additionally, many viral fusion proteins also induce cell-cell fusion, i.e., the formation of multinucleated syncytia, facilitating the rapid spread of virus infection.TThe spike (S) protein of coronaviruses is responsible for receptor binding and membrane fusion. It shares similarity with class I virus fusion proteins (2, 3). Typically, it is a type I integral membrane protein, which is N-glycosylated and trimerized in the endoplasmic reticulum. The N-terminal S1 protein contains the receptor-binding site (10,18,22,34). The C-terminal S2 protein is a fusion subunit and anchors on the viral envelope through a transmembrane domain. The S2 protein ectodomain contains two 4,3 hydrophobic heptad repeats (HR1 and HR2) and a putative, internal fusion peptide (3, 23). For the SARS-CoV S protein, the HR2 is located adjacent to the transmembrane domain, whereas the HR1 is 140 to 170 residues upstream of the HR2.Crystallographic, biophysical, and biochemical analysis of the fusion core of SARS-CoV S protein (2,12,19,27,30,35) and other class I fusion proteins (8, 25) supports a model of membrane fusion probably adopted by these enveloped viruses. After the attachment of the receptor-binding subunit to the receptor, the HR1 and HR2 domains in the membrane fusion subunit interact with each other and form a six-helix bundle, a complex consisting of a homotrimeric HR1 coiled coil surrounded by three HR2 helices. The spacer domain (or link, or interhelical domain) between HR1 and HR2 forms a loop and reverses the direction of the polypeptide chain so that the HR2 helices pack against the HR1 coiled coil in an antiparallel manner. This conformational change results in a close apposition of the fusion peptide, already exposed and inserted into th...
Current smallpox vaccines are live vaccinia viruses that replicate in the vaccinee inducing immunity against the deadly disease smallpox. Replication resulting in virus spread within the host, however, is the major cause of severe postvaccinal adverse events. Therefore, attenuated strains such as modified vaccinia Ankara (MVA) or LC16m8 are candidates as next generation vaccines. These strains are usually grown in primary cells in which mass production is difficult and have an unknown protective potential in humans. Proven vaccine strains of defined origin and modern production techniques are therefore desirable. In this study, defective vaccinia virus (dVV) lacking a gene essential for replication (derived from the Lister vaccine in a complementing cell line) was compared with the Wyeth smallpox vaccine strain and with MVA in mouse animal models using cowpox and ectromelia virus challenge. Similar to MVA, prime-boost immunizations with defective vaccinia induced robust long-term immunity, suggesting it as a promising next generation smallpox vaccine.
We report the rescue of a defective vaccinia virus, forming the basis for a stringent selection protocol to generate replicating recombinant virus without the need for marker cassettes and selection agents. Plaques of recombinant virus could be isolated solely by their ability to grow in wild-type cells normally supporting the growth of vaccinia virus. All growth-competent clones analyzed contained the gene of interest in the intended genomic locus and displayed foreign gene expression to the same levels as was seen with classical recombinants obtained by insertion into the vaccinia virus thymidine kinase locus. The system is based on a defective vaccinia virus, expressing exclusively early genes, termed eVAC-1, and an insertion plasmid vector providing the essential function, the uracil DNA glycosylase gene. In addition, the defective virus is free of selection and color marker genes, thus also representing a basic vector for the generation of defective recombinants.
The timely development of safe and effective vaccines against avian influenza virus of the H5N1 subtype will be of the utmost importance in the event of a pandemic. Our aim was first to develop a safe live vaccine which induces both humoral and cell-mediated immune responses against human H5N1 influenza viruses and second, since the supply of embryonated eggs for traditional influenza vaccine production may be endangered in a pandemic, an egg-independent production procedure based on a permanent cell line. In the present article, the generation of a complementing Vero cell line suitable for the production of safe poxviral vaccines is described. This cell line was used to produce a replication-deficient vaccinia virus vector H5N1 live vaccine, dVV-HA5, expressing the hemagglutinin of a virulent clade 1 H5N1 strain. This experimental vaccine was compared with a formalin-inactivated whole-virus vaccine based on the same clade and with different replicating poxvirus-vectored vaccines. Mice were immunized to assess protective immunity after high-dose challenge with the highly virulent A/Vietnam/1203/2004(H5N1) strain. A single dose of the defective live vaccine induced complete protection from lethal homologous virus challenge and also full cross-protection against clade 0 and 2 challenge viruses. Neutralizing antibody levels were comparable to those induced by the inactivated vaccine. Unlike the whole-virus vaccine, the dVV-HA5 vaccine induced substantial amounts of gamma interferon-secreting CD8 T cells. Thus, the nonreplicating recombinant vaccinia virus vectors are promising vaccine candidates that induce a broad immune response and can be produced in an egg-independent and adjuvant-independent manner in a proven vector system.
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