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)

Fresh frozen plasma (FFP) is prepared in blood banks world-wide as a by-product of red blood cell concentrate preparation. Appropriate clinical use is for coagulation factor disorders where appropriate concentrates are unavailable and when multiple coagulation factor deficits occur such as in surgery. Viral safety depends on donor selection and screening; thus, there continues to be a small but defined risk of viral transmission comparable with that exhibited by whole blood. We have prepared a virus sterilized FFP (S/D-FFP) by treatment of FFP with 1% tri(n-butyl)phosphate (TNBP) and 1% Triton X-100 at 30 degrees C for 4 hours. Added reagents are removed by extraction with soybean oil and chromatography on insolubilized C18 resin. Treatment results in the rapid and complete inactivation of greater than or equal to 10(7.5) infectious doses (ID50) of vesicular stomatitis virus (VSV) and greater than or equal to 10(6.9) ID50 of sindbis virus (used as marker viruses), greater than or equal to 10(6.2) ID50 of human immunodeficiency virus (HIV), greater than or equal to 10(6) chimp infectious doses (CID50) of hepatitis B virus (HBV), and greater than or equal to 10(5) CID50 of hepatitis C virus (HCV). Immunization of rabbits with S/D-FFP and subsequent adsorption of elicited antibodies with untreated FFP confirmed the absence of neoimmungen formation. Coagulation factor content was comparable with that found in FFP. Based on these laboratory and animal studies, together with the extensive history of the successful use of S/D-treated coagulation factor concentrates, we conclude that replacement of FFP with S/D-FFP, prepared in a manufacturing facility, will result in improved virus safety and product uniformity with no loss of efficacy.
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PMID:Solvent/detergent-treated plasma: a virus-inactivated substitute for fresh frozen plasma. 131 64

Laboratory research that began in 1982 led to the licensing in the USA of a solvent/detergent (SD)-treated factor VIII concentrate in 1985. The licence was granted on the basis of several factors. First, studies had demonstrated the inactivation of several marker viruses (vesicular stomatitis virus, Sindbis virus, Sendai virus) and other viruses such as human immunodeficiency virus (HIV), hepatitis B virus (HBV), and non-A, non-B hepatitis virus (NANBHV; now known principally to be hepatitis C virus) added to the factor VIII concentrate just before treatment. Secondly, it had been realized that the relevant viruses in transfusion (e.g. HIV, HBV, NANBHV) all had lipid envelopes. Finally, laboratory, preclinical and clinical evidence indicated that factor VIII and other proteins present in the preparation were unaffected by SD treatment. The applicability of the SD method to a wide range of products and preparations, high process recoveries and a growing body of viral safety information linked with the failure of several other virus-inactivation methods to eliminate hepatitis transmission fostered the adoption of SD technology by more than 50 organizations worldwide. SD mixtures are now used in the preparation of a diverse array of products. Numerous laboratory and clinical studies suggest that coagulation-factor concentrates and other SD-treated products prepared from plasma pools are now safer than the individual units from which they were derived. Also, a large body of evidence indicates that hepatitis A virus (HAV) is not typically transmitted by blood and blood products.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Viral safety of solvent/detergent-treated blood products. 774 45

We report here the results of our evaluation of virus inactivation during the manufacturing steps of two intravenous immunoglobulin (IGIV) preparations. Virus inactivation and/or removal by processing steps, such as ethanol fractionation and polyethylene glycol precipitation, and deliberate virucidal steps, such as solvent/detergent treatment and pasteurization, were tested on a variety of human pathogenic and experimental model viruses, including human immunodeficiency, Hepatitis C, Mumps, Vaccinia, Chikungunya, Vesicular Stomatitis, Sindbis, and ECHO viruses. All viruses were successfully inactivated and/or eliminated by the processing steps studied. In some cases, however, multiple steps were required. We conclude that the incorporation of steps deliberately designed to inactivate or remove viruses during the production of IGIV provides an extra measure of viral safety.
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PMID:Inactivation and elimination of viruses during preparation of human intravenous immunoglobulin. 786 23

Intravenous immunoglobulins and serum protein solutions are manufactured from human plasma pools of healthy, screened donors. A step-by-step validation of virus removal and/or inactivation was performed for the manufacturing process, which includes cold ethanol fractionation, beta-propiolactone (beta-PL) treatment, UV irradiation, thermal inactivation and other chemical and physical purification steps. The total viral clearance factors achieved for the entire manufacturing process were by several magnitudes greater than the potential virus load of current plasma pools. Human immunodeficiency virus 1 (HIV-1) infectivity was reduced by > 13.4 log for 7S immunoglobulin, > 15.3 log for IGM enriched immunoglobulin and > 16 log for a 5% serum protein solution. In addition, high clearance rate for a broad spectrum of model viruses was demonstrated for all three blood derivatives being > 23.2 to > 27.8 log for pseudo rabies virus (PSR), > 12.3 to > 22.6 log for vesicular stomatitis virus (VSV) and 6.9-10.6 log for simian virus 40 (SV40). For the beta-propiolactone inactivation step Hepatitis C model viruses, e.g. equine arteritis virus (EAV) and bovine viral diarrhoea virus (BVDV) were also investigated.
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PMID:Validation of virus inactivation and removal for the manufacturing procedure of two immunoglobulins and a 5% serum protein solution treated with beta-propiolactone. 811 39

Laboratory research commencing in 1982 led to licensing in the United States in 1985 of a solvent/detergent (SD)-treated anti-haemophilic factor (AHF) concentrate. Licensing was based on (a) studies demonstrating the inactivation of several marker viruses [vesicular stomatitis virus (VSV), Sindbis virus, Sendai virus], human immunodeficiency virus (HIV), hepatitis B virus (HBV), and non-A, non-B hepatitis virus [NANBHV; now known to be principally hepatitis C virus (HCV)] added to AHF just before treatment, (b) the realization that the principal viruses of concern in a transfusion setting (e.g. HIV, HBV, NANBHV) were all lipid-enveloped, and (c) laboratory, preclinical and clinical evidence indicating that AHF and other proteins present in the preparation were unaffected. The applicability of the SD method to a wide range of products and preparations, high process recoveries, and a growing body of viral safety information linked with the failure of several other virus inactivation methods to eliminate hepatitis transmission fostered the adoption of SD technology by more than 50 organizations world-wide. SD mixtures are now used in the preparation of products as diverse as intermediate purity and monoclonal antibody purified AHF and other coagulation factor concentrates, fibrin glue, normal and hyperimmune IgG and IgM preparations including those derived from tissue culture, plasma for transfusion, and various diagnostic controls. Over four million doses of SD-treated products have been administered, and numerous laboratory and clinical studies designed to assess virus safety have been conducted. SD treatment has been shown to inactivate > or = 10(9.2) tissue culture infectious doses (TCID50) of VSV, > or = 10(8.8) TCID50 of Sindbis virus, > or = 10(6.0) TCID50 of Sendai virus, > or = 10(7.3) duck infectious doses of duck HBV, > or = 10(11.0) degrees TCID50 of HIV-1, > or = 10(6.0) TCID50 of HIV-2, > or = 10(6.0) chimpanzee infectious doses (CID50) of HBV, > or = 10(5.0) CID50 of HCV, > or = 10(6.0) TCID50 of cytomegalovirus, > or = 10(5.8) TCID50 of herpes simplex virus type 1, > or = 10(4.0) TCID50 of PI-1, > or = 10(6.0) TCID50 of murine leukemia virus (Mov-3), > or = 10(4.0) TCID50 of murine xenotropic virus, and > or = 10(2.0) TCID50 of Rauscher murine leukemia ecotropic virus. Moreover, in ten prospective clinical studies, 0/53, 0/427, and 0/455 patients susceptible to HBV, NANBHV (HCV), and HIV became infected on follow-up.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Viral safety of solvent-detergent treated blood products. 817 97

The putative envelope glycoproteins of hepatitis C virus (HCV) likely play an important role in the initiation of viral infection. Available information suggests that the genomic regions encoding the putative envelope glycoproteins, when expressed as recombinant proteins in mammalian cells, largely accumulate in the endoplasmic reticulum. In this study, genomic regions which include the putative ectodomain of the E1 (amino acids 174 to 359) and E2 (amino acids 371 to 742) glycoproteins were appended to the transmembrane domain and cytoplasmic tail of vesicular stomatitis virus (VSV) G protein. This provided a membrane anchor signal and the VSV incorporation signal at the carboxy termini of the E1 and E2 glycoproteins. The chimeric gene constructs exhibited expression of the recombinant proteins on the cell surface in a transient expression assay. When infected with a temperature-sensitive VSV mutant (ts045) and grown at the nonpermissive temperature (40.5 degrees C), cells transiently expressing the E1 or E2 chimeric glycoprotein generated VSV/HCV pseudotyped virus. The resulting pseudotyped virus generated from E1 or E2 surprisingly exhibited the ability to infect mammalian cells and sera derived from chimpanzees immunized with the homologous HCV envelope glycoproteins neutralized pseudotyped virus infectivity. Results from this study suggested a potential functional role for both the E1 and E2 glycoproteins in the infectivity of VSV/HCV pseudotyped virus in mammalian cells. These observations further suggest the importance of using both viral glycoproteins in a candidate subunit vaccine and the potential for using a VSV/HCV pseudotyped virus to determine HCV neutralizing antibodies.
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PMID:Functional role of hepatitis C virus chimeric glycoproteins in the infectivity of pseudotyped virus. 955 33

Noncytopathic replicons of the flavivirus Kunjin (KUN) were employed for expression and delivery of heterologous genes. Replicon vector C20DX2Arep, containing a unique cloning site followed by the sequence of 2A autoprotease of foot-and-mouth disease virus, was constructed and used for expression of a number of heterologous genes including chloramphenicol acetyltransferase (CAT), green fluorescent protein (GFP), beta-galactosidase, glycoprotein G of vesicular stomatitis virus, and the Core and NS3 genes of hepatitis C virus. The expression and proper processing of these genes upon transfection of BHK21 cells with the recombinant replicon RNAs were demonstrated by immunofluorescence, radioimmunoprecipitation, and appropriate reporter gene assays. Most of these recombinant KUN replicon RNAs were also successfully packaged into secreted virus-like particles (VLPs) by subsequent transfection with Semliki Forest virus replicon RNA expressing KUN structural genes. Infection of BHK21 and Vero cells with these VLPs resulted in continuous replication of the recombinant replicon RNAs and prolonged expression of the cloned genes without any cytopathic effect. We also developed a replicon vector for generation of stable cell lines continuously expressing heterologous genes by inserting an encephalomyelocarditis virus internal ribosomal entry site-neomycin transferase gene cassette into the 3'-untranslated region of the C20DX2Arep vector. Using this vector (C20DX2ArepNeo), stable BHK cell lines persistently expressing GFP and CAT genes for up to 17 passages were established. Thus noncytopathic KUN replicon vectors with the ability to be packaged into VLPs should provide a useful tool for the development of noninfectious and noncytopathic vaccines as well as for gene therapy applications.
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PMID:Noncytopathic flavivirus replicon RNA-based system for expression and delivery of heterologous genes. 1006 62

The hepatitis C virus (HCV) nonstructural 5A (NS5A) protein has been implicated in the inherent resistance of HCV to interferon (IFN) antiviral therapy in clinical studies. Biochemical studies have demonstrated that NS5A interacts in vitro with and inhibits the IFN-induced, RNA-dependent protein kinase, PKR, and that NS5A interacts with at least one other cellular kinase. The present study describes the establishment and characterization of various stable NS5A-expressing human cell lines, and the development of a cell culture-based assay for determining the inherent IFN resistance of clinical NS5A isolates. Human epithelioid (Hela) and osteosarcoma (U2-OS) cell lines were generated that express NS5A under tight regulation by the tetracycline-dependent promoter. Maximal expression of NS5A occurred at 48 hours following the removal of tetracycline from the culture medium. The half-life of NS5A in these cell lines was between 4 to 6 hours. NS5A protein expression was localized cytoplasmically, with a staining pattern consistent with the location of the Golgi apparatus and endoplasmic reticulum. In the majority of cell lines, no obvious phenotypic changes were observed. However, three genotype 1b NS5A-expressing osteosarcoma cell lines exhibited cytopathic effect and severely reduced proliferation as a result of high-level NS5A expression. Full-length NS5A protein isolated from a genotype 1b IFN-nonresponsive patient (NS5A-1b) was capable of rescuing encephalomyocardititis virus replication during IFN challenge up to 40-fold, whereas a full-length NS5A-1a and an interferon sensitivity determining region (ISDR) deletion mutant (NS5A-1a-triangle upISDR) isolated from a genotype 1a IFN-nonresponsive patient showed no rescue activity. The NS5A-1b and NS5A-1a proteins also rescued vesicular stomatitis virus replication during IFN treatment by two- to threefold. These data cummulatively suggest that NS5A expression alone can render cells partially resistant to the effects of IFN against IFN-sensitive viruses, and that in some systems, these effects may be independent of the putative ISDR. A scenario is discussed in which the NS5A protein may employ multiple strategies contributing to IFN resistance during HCV infection.
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PMID:Characterization of the effects of hepatitis C virus nonstructural 5A protein expression in human cell lines and on interferon-sensitive virus replication. 1009 74

The non-structural protein 5A (NS5A) of some hepatitis C virus (HCV) isolates has been implicated in the inhibition of the antiviral activity of interferon (IFN). In the present study, the possible inhibitory effects of NS5A from two isolates of HCV subtype 1b, HCV-1bJk and M094AJk, and their chimeric form on the antiviral activity of IFN were examined. HCV-1bJk and M094AJk are categorized as IFN resistant and IFN sensitive, respectively, based on the sequences of the IFN-sensitivity determining region (ISDR). When encephalomyocarditis virus was used as a challenge virus, NS5A was shown to eliminate the antiviral activity of IFN, with inhibition being more prominent with HCV-1bJk NS5A than with M094AJk NS5A. Moreover, the inhibition was significantly weaker in cells expressing a chimeric NS5A that had a short stretch of 49 amino acids (aa 2209-2257), including the ISDR sequence, from M094AJk in the backbone of the HCV-1bJk sequence than in cells expressing the original NS5A from HCV-1bJk. These results suggest an important role for the 49 aa sequence, including the ISDR, in the inhibition of IFN-mediated antiviral activity. On the other hand, only a slight reduction of IFN antiviral activity by HCV-1bJk NS5A was observed when vesicular stomatitis virus was used as a challenge virus, and barely any reduction was observed when Japanese encephalitis virus was used. These results may reflect differential importance of each of the IFN-mediated signalling pathways in conferring resistance against different viruses.
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PMID:The NS5A protein of hepatitis C virus partially inhibits the antiviral activity of interferon. 1021 56

Hepatitis C virus (HCV) is prevalent worldwide and has become a major cause of liver dysfunction and hepatocellular carcinoma. The high prevalence of HCV reflects the persistent nature of infection and the large frequency of cases that resist the current interferon (IFN)-based anti-HCV therapeutic regimens. HCV resistance to IFN has been attributed, in part, to the function of the viral nonstructural 5A (NS5A) protein. NS5A from IFN-resistant strains of HCV can repress the PKR protein kinase, a mediator of the IFN-induced antiviral and apoptotic responses of the host cell and a tumor suppressor. Here we examined the relationship between HCV persistence and resistance to IFN therapy. When expressed in mammalian cells, NS5A from IFN-resistant HCV conferred IFN resistance to vesicular stomatitis virus (VSV), which normally is sensitive to the antiviral actions of IFN. NS5A blocked viral double-stranded RNA (dsRNA)-induced PKR activation and phosphorylation of eIF-2alpha in IFN-treated cells, resulting in high levels of VSV mRNA translation. Mutations within the PKR-binding domain of NS5A restored PKR function and the IFN-induced block to viral mRNA translation. The effects due to NS5A inhibition of PKR were not limited to the rescue of viral mRNA translation but also included a block in PKR-dependent host signaling pathways. Cells expressing NS5A exhibited defective PKR signaling and were refractory to apoptosis induced by exogenous dsRNA. Resistance to apoptosis was attributed to an NS5A-mediated block in eIF-2alpha phosphorylation. Moreover, cells expressing NS5A exhibited a transformed phenotype and formed solid tumors in vivo. Disruption of apoptosis and tumorogenesis required the PKR-binding function of NS5A, demonstrating that these properties may be linked to the IFN-resistant phenotype of HCV.
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PMID:Antiapoptotic and oncogenic potentials of hepatitis C virus are linked to interferon resistance by viral repression of the PKR protein kinase. 1040 Jul 46


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