UMLS:C0038362 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0038362 (stomatitis)
8,852 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Immunoisolation techniques have led to the purification of apical and basolateral transport vesicles that mediate the delivery of proteins from the trans-Golgi network to the two plasma membrane domains of MDCK cells. We showed previously that these transport vesicles can be formed and released in the presence of ATP from mechanically perforated cells (Bennett, M. K., A. Wandinger-Ness, and K. Simons, 1988. EMBO (Euro. Mol. Biol. Organ.) J. 7:4075-4085). Using virally infected cells, we have monitored the purification of the trans-Golgi derived vesicles by following influenza hemagglutinin or vesicular stomatitis virus (VSV) G protein as apical and basolateral markers, respectively. Equilibrium density gradient centrifugation revealed that hemagglutinin containing vesicles had a slightly lower density than those containing VSV-G protein, indicating that the two fractions were distinct. Antibodies directed against the cytoplasmically exposed domains of the viral spike glycoproteins permitted the resolution of apical and basolateral vesicle fractions. The immunoisolated vesicles contained a subset of the proteins present in the starting fraction. Many of the proteins were sialylated as expected for proteins existing the trans-Golgi network. The two populations of vesicles contained a number of proteins in common, as well as components which were enriched up to 38-fold in one fraction relative to the other. Among the unique components, a number of transmembrane proteins could be identified using Triton X-114 phase partitioning. This work provides evidence that two distinct classes of vesicles are responsible for apical and basolateral protein delivery. Common protein components are suggested to be involved in vesicle budding and fusion steps, while unique components may be required for specific recognition events such as those involved in protein sorting and vesicle targeting.
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PMID:Distinct transport vesicles mediate the delivery of plasma membrane proteins to the apical and basolateral domains of MDCK cells. 220 40

The treatment of plasma with organic solvent/detergent mixtures at the time of plasma collection or pooling could reduce the exposure of technical staff to infectious viruses and enhance the viral safety of the final product. Treatment of plasma for 4 hours with 2-percent tri(n-butyl)phosphate (TNBP) at 37 degrees C, with 1-percent TNBP and 1-percent polyoxyethylensorbitan monooleate (Tween 80) at 30 degrees C, or with 1-percent TNBP and 1-percent polyoxyethylene ethers, (Triton X-45) at 30 degrees C resulted in the rapid and complete inactivation of greater than or equal to 10(4) tissue culture-infectious doses (TCID50) of vesicular stomatitis and Sindbis viruses, which are used as surrogates. Treatment of plasma with TNBP and TNBP and Tween-80 was shown to inactivate greater than or equal to 10(4) TCID50 of human immunodeficiency virus. TNBP treatment of plasma contaminated with 10(6) chimpanzee-infectious doses (CID50) of hepatitis B virus and 10(5) CID50 of non-A,non-B hepatitis virus prevented the transmission of hepatitis to chimpanzees. Immediately after treatment of plasma with 2-percent TNBP, the recovery of factors VIII, IX, and V and antithrombin III was 80, 90, 40, and 100 percent, respectively. Recovery of all factors was greater than or equal to 90 percent after treatment with TNBP and detergent mixtures. Treated plasma was fractionated by standard techniques into antihemophilic factor and prothrombin complex concentrates, immune globulin, and albumin. Prior treatment with TNBP or TNBP and detergent did not affect the separations of desired proteins. Therefore, it appears possible to inactivate viruses in plasma before the execution of standard fractionation procedures.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The use of tri(n-butyl)phosphate detergent mixtures to inactivate hepatitis viruses and human immunodeficiency virus in plasma and plasma's subsequent fractionation. 175 94

Reconstituted vesicular stomatitis virus (VSV) envelopes were formed by solubilization of the viral envelope with Triton X-100 followed by removal of detergent by direct addition of SM2 biobeads. We provide direct demonstration of fusion of reconstituted VSV with cells using fluorescent lipid and aqueous probes incorporated into the VSV virosomes during reconstitution. We show a direct comparison of the kinetics and pH profile of fusion with cells between reconstituted VSV and fluorescently labeled intact virus. With this preparation it is now possible to gain additional information about the role of cooperativity in viral protein-mediated fusion, and to permit construction of efficient vehicles for delivery of drugs and other materials into cells.
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PMID:pH-dependent fusion of reconstituted vesicular stomatitis virus envelopes with Vero cells. Measurement by dequenching of fluorescence. 253 31

Goose erythrocyte membranes were isolated and tested for their ability to compete with red cell receptors for vesicular stomatitis virus (VSV) attachment and fusion at acidic pH. Crude membranes, solubilized with Triton X-100, Tween 80 and octyl-beta-D-glucopyranoside, showed a dose-dependent inhibitory effect on virus binding and haemolysis. The chemical nature of the active molecules was investigated by enzyme digestion and by separation of purified components. Only the lipid moiety, specifically phospholipid and glycolipid, was found to inhibit VSV attachment; a more detailed analysis of these molecules showed that phosphatidylinositol, phosphatidylserine and GM3 ganglioside were responsible for the inhibitory activity and could therefore represent VSV binding sites on goose erythrocyte membranes. Removal of negatively charged groups from these molecules by enzymic treatment significantly reduced their activity, suggesting that electrostatic interactions play an important role in the binding of VSV to the cell surface. Enzymic digestion of whole erythrocytes confirmed the involvement of membrane lipid molecules in the cell surface receptor for VSV.
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PMID:Characterization of membrane components of the erythrocyte involved in vesicular stomatitis virus attachment and fusion at acidic pH. 282 Nov 75

Phosphorylation of membrane-associated proteins by protein kinases in the membrane fraction from HeLa S3 cells was rapidly increased when the cells were infected with vesicular stomatitis virus (VSV). SDS-PAGE followed by autoradiography revealed polypeptides with molecular sizes of Mr. 53,000, 44,000, 42,000, 35,000, 30,000 and 27,000 in the kinase fraction from uninfected cells to be highly phosphorylated. Virus-coding NS protein (Mr. 40,000) was phosphorylated when the membrane fraction from virus-infected cells was incubated with [gamma-32P]ATP in the presence of histone H1 and Mg2+. Under these conditions, histone H1 functioned as a stimulator for NS protein phosphorylation by the kinases. One (kinase III) of the membrane-associated kinases was partially purified from HeLa S3 cells using FPLC (type Mono Q) after DEAE-cellulose column chromatography. The enzymatic properties of kinase III were similar to those reported for a polypeptide-dependent protein kinase (protein kinase P), because (a) both kinases highly phosphorylated beta-casein, although no phosphorylation was observed with histones; (b) several endogenous substrates from HeLa S3 cell membrane were phosphorylated by the kinases in the presence of basic proteins, such as histones, protamine and poly-Lys; (c) their activity was insensitive to a low concentration (19 micrograms/ml) of heparin, which highly inhibited casein kinase II activity; and (d) the kinases were extractable from the plasma membrane using Triton X-100. In addition, provided evidence suggests that kinase III may play an important role in an early stage of VSV replication through its specific phosphorylation of NS protein and membrane proteins in virus infected cells.
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PMID:Characterization of a polypeptide-dependent membrane protein kinase that specifically phosphorylates NS protein of vesicular stomatitis virus in vitro. 284 89

When vesicular stomatitis virus was incubated with Saccharomyces cerevisiae spheroplasts at 37 degrees C, part of the virus was internalized by the spheroplasts as shown by the following criteria. (i) The spheroplast-associated virus was protected from proteinase K digestion, which releases surface-bound virus by degrading the envelope glycoproteins. (ii) The spheroplast-associated virus was resistant to mild Triton X-100 treatment, which readily solubilizes the virus. The same results were obtained with Semliki Forest virus. Internalization of the two viruses followed linear kinetics up to 90 min at 37 degrees C. Internalization was concentration- and temperature-dependent. At 11 degrees C no uptake could be detected for at least 2 h. Homogenization and organelle fractionation protocols were designed for the S. cerevisiae spheroplasts to study the compartments into which the virions were internalized. Three compartments containing both marker viruses could be separated in density gradients. One coincided with vacuole markers, one banded at a slightly higher and one at a similar density to the plasma membrane markers. Thus, S. cerevisiae spheroplasts appear to have the capability of endocytosing particulate markers like viruses. The companion paper describes internalization of two soluble macromolecules, alpha-amylase and fluorescent dextran, into intact cells.
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PMID:Endocytosis in Saccharomyces cerevisiae: internalization of enveloped viruses into spheroplasts. 299 48

The association of poliovirus metabolism with the cytoskeleton was investigated. Infected cells were extracted by using the nonionic detergent Triton X-100 in the physiological cytoskeleton buffer. The skeletal framework obtained was examined by transmission electron microscopy of resinless sections. The fibers of the framework were grossly distorted in infected cells. No virions or procapsids were seen but many virus-specific spheroidal bodies were associated with the framework. They had a diameter of 40 to 70 nm, were characterized by a dense core and a translucent periphery, and occurred in strings, often near the remnants of flattened vesicles. These spheres may correspond to virus-synthesizing bodies. The metabolism of poliovirus RNA was shown to be associated with the skeletal framework by pulse-labeling cells with [3H]uridine and measuring the RNA retained on the framework. 20S double-stranded RNA, a form of poliovirus RNA found only in the replication complex, was attached to the skeleton throughout a 60-min pulse-label. 35S single-stranded viral RNA, a form found in virions, in polyribosomes, and in the replication complex, appeared first on the framework but after a few minutes was also found in the soluble cytoplasmic phase, encapsidated in virions. In contrast to viral RNA, viral proteins exhibited a varied association with the skeletal framework. Viral proteins were pulse-labeled with [35S]methionine and chased with unlabeled methionine. Although all of the virus-specific proteins were found, to some extent, in the skeletal fraction, the derivatives of P2 (P2-X and P2-5) and a derivative of P3 (P3-2) showed a preferential association with the skeletal framework. Virions and procapsids, on the other hand, were not associated with the cytoskeleton; both they and their component proteins (P1-VP0, P1-VP1, P1-VP2, and P1-VP3) were found dominantly in the soluble cytoplasmic phase. The pathway of poliovirus assembly can be inferred from the above data. It is different from that found previously for the enveloped vesicular stomatitis virus and may be representative of encapsidated cytoplasmic virus assembly.
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PMID:Poliovirus metabolism and the cytoskeletal framework: detergent extraction and resinless section electron microscopy. 299 75

The nucleocapsid of vesicular stomatitis virus (VSV) was introduced into the cytoplasm of Saccharomyces cerevisiae by low pH-dependent fusion of the viral envelope with the spheroplast plasma membrane. This led to de novo synthesis of the three major structural proteins of the virus--the G, N, and M proteins--as shown by immunoprecipitation of [35S]methionine-labeled spheroplast lysates. In NaDodSO4/polyacrylamide gel electrophoresis, M and N proteins comigrated with those of the virion, whereas the yeast-made G protein migrated as two bands with apparent molecular sizes of 60 and 70 kDa. Both polypeptides appeared to be N-glycosylated, since only one polypeptide with the apparent molecular mass of approximately equal to 55 kDa was produced in the presence of tunicamycin. Phase separation into Triton X-114 suggested that the unglycosylated G protein was membrane bound. According to immunofluorescent surface staining of live spheroplasts, at least part of the G protein was transported to the plasma membrane. Spheroplasts expressing the VSV genes could be fused together by low pH to form polykaryons, indicating that G protein synthetized by yeast was fusogenic--i.e., biologically active.
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PMID:Expression of the RNA genome of an animal virus in Saccharomyces cerevisiae. 302 81

The purpose of this paper is to describe the immunocytochemical localization of M protein of vesicular stomatitis virus (VSV) in infected cells. Vero cells, MDBK cells, Swiss 3T3 cells, and BHK cells were examined at various times after infection. For immunofluorescent staining, the cells were fixed with PLP fixative and then treated with 0.05% Triton X-100 before incubation with antibodies. Three hours after infection, M protein exhibited diffuse immunostaining throughout the cytoplasm and later accumulated along the cell membrane. The localization of M protein differed from the granular localization of the nucleocapsid N protein of VSV in the cytoplasm. For electron microscopy, the cells were fixed first in a mixture of 2% paraformaldehyde and 0.05% glutaraldehyde and then with PLP fixative, this being followed by treatment with 0.05% saponin. They were then immunostained using the immunoperoxidase method. The M protein was found to be distributed throughout the cytoplasm and later under the cell membrane, especially at virus budding sites. We also used postembedding immunostaining and freeze-fracture immunostaining to avoid the translocation of M protein caused by the detergent treatment. These techniques confirmed our previous results. Our findings are consistent with the view that the M protein of VSV is synthesized on free ribosomes and is then associated with the cell membrane where viral assembly may occur.
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PMID:Immunocytochemical study of the intracellular localization of M protein of vesicular stomatitis virus. 303 95

Cholesterol present in intact brush-border membrane vesicles made from rabbit small intestine is a poor substrate for cholesterol oxidase (EC 1.1.3.6, from Nocardia sp. and Nocardia erythropolis). It becomes susceptible to oxidation by the enzyme only after the addition of detergent, e.g., Triton X-100, in quantities sufficient to disrupt the membrane. This is also true for cholesterol present in bilayers of small unilamellar phosphatidylcholine or phosphatidylserine vesicles made by ultrasonication. The data presented here on intestinal brush-border membrane are in good agreement with results reported on other biological membranes, e.g., from erythrocytes and vesicular stomatitis virus, but are somewhat different from those on rat intestinal brush-border membrane. Our results on phospholipid bilayers agree well with published work on model membranes. From the work presented we conclude that, with our present understanding, cholesterol oxidase can hardly be used to probe the distribution of cholesterol in biological membranes. A prerequisite for using the enzyme successfully as such a probe would be the understanding of the factors controlling the interaction of the enzyme with its substrate cholesterol. The question under which conditions cholesterol oxidase could be useful for probing the distribution and preferred location of cholesterol in biological membranes is discussed.
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PMID:Cholesterol oxidase as a structural probe of biological membranes: its application to brush-border membrane. 345

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