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...
CTL clear virus-infected cells and tumorigenic cells by releasing potent cytotoxic enzymes stored in preformed lytic granules. The exocytosis process includes polarization of lytic granules toward the immunological synapse, tethering of lytic granules to the plasma membrane and finally fusion of lytic granules with the plasma membrane to release cytotoxic enzymes. Although much is known about the molecular machineries necessary for the earlier steps in lytic granule exocytosis, the molecular machinery governing the final step in the fusion process has not been identified. Here, we show using control and VAMP8 KO mice that VAMP8 is localized to the CTL lytic granules. While the immunological synapse and granule polarization appears normal in both VAMP8 KO and control CTL, CTL-mediated killing was reduced for the Vamp8 -/-CTL. Analysis of lytic enzyme secretion demonstrated that granzyme A and granzyme B secretion is significantly compromised in VAMP8 -/-CTL, while the levels of the lytic enzymes in the cells are unaffected. Our results clearly show that VAMP8 is one of the v-SNARE that regulate the lytic ability of CTL by influencing the ability of the lytic granules to fuse with the plasma membrane and release its contents.
The hemagglutinin (HA) of influenza A virus plays an essential role in mediating the entry of the virus into host cells. Here, recombinant full-length HA5 protein from a H5N1 isolate (A/ chicken/hatay/2004(H5N1)) was expressed and purified from the baculovirus-insect cell system. As expected, full-length HA5 elicits strong neutralizing antibodies, as evaluated in microneutralization tests using HA5 pseudotyped lentiviral particles. In addition, two fragments of HA5 were expressed in bacteria and the N-terminal fragment, covering the ectodomain before the HA1/HA2 polybasic cleavage site, was found to elicit neutralizing antibodies. But the C-terminal fragment, which covers the remaining portion of the ectodomain, did not. Neutralizing titer of the anti-serum against the N-terminal fragment is only four times lower than the antiserum against the full-length HA5 protein. Using a novel membrane fusion assay, the abilities of these antibodies to block membrane fusion were found to correlate well with the neutralization activities.
The large number of mutations identified across all cancers represents an untapped reservoir of targets that can be useful for therapeutic targeting if highly selective, mutation-specific reagents are available. We report here our attempt to generate such reagents: monoclonal antibodies against the most common R175H, R248Q, and R273H hotspot mutants of the tumor suppressor p53. These antibodies recognize their intended specific alterations without any cross-reactivity against wild-type (WT) p53 or other p53 mutants, including at the same position (as exemplified by anti-R248Q antibody, which does not recognize the R248W mutation), evaluated by direct immunoblotting, immunoprecipitation, and immunofluorescence methods on transfected and endogenous proteins. Moreover, their clinical utility to diagnose the presence of specific p53 mutants in human tumor microarrays by immunohistochemistry is also shown. Together, the data demonstrate that antibodies against specific single-amino-acid alterations can be generated reproducibly and highlight their utility, which could potentially be extended to therapeutic settings.
The integral membrane glycoprotein BARP associates with voltage-gated calcium channel Cavβ subunits, disrupting their association with Cavα1 subunits and suppressing overall channel activity.
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